Tumor necrosis factor-alpha and interleukin 1-alpha regulate transferrin receptor in human diploid fibroblasts. Relationship to the induction of ferritin heavy chain

We have studied transferrin receptor expression in MRC5 human fibroblasts in response to tumor necrosis factor-alpha (TNF, cachectin) or interleukin 1-alpha (IL-1). Treatment of exponentially growing MRC5 cells with these cytokines led to a 3-4-fold increase in transferrin receptor mRNA and a coordinate increase in transferrin receptor protein by 24 h. Under these conditions, stimulation of [3H]thymidine incorporation was minimal, suggesting that the induction of transferrin receptor by TNF and IL-1 is mediated by a growth-independent regulatory mechanism. A study of the time course of this response showed that cytokine-mediated increases in transferrin receptor mRNA and protein proceeded after a lag of 12-24 h. A simultaneous analysis of the effects of TNF and IL-1 on ferritin in MRC5 cells was also performed. Ferritin L mRNA levels were unchanged. However, induction of ferritin H mRNA was seen within 4 h, preceding the induction of the transferrin receptor. The synthesis of ferritin H (but not ferritin L) protein peaked at 8 h after TNF or IL-1 treatment, followed by a rapid decrease in both ferritin H and L protein synthesis. As ferritin H synthesis declined, levels of transferrin receptor protein increased, reaching a maximum by 24 h. These results suggest that the cytokine-dependent induction of ferritin H and subsequent increase in the transferrin receptor are related and possibly interdependent events. This study demonstrates that the complex role of TNF and IL-1 in iron homeostasis includes modulation of the transferrin receptor.     

Interleukin 1 induces ferritin heavy chain in human muscle cells

Interleukin 1 alpha (IL-1) and tumor necrosis factor alpha (TNF) are two monokines which play a prominent role in the response to inflammation and injury. We recently observed that TNF leads to an increase in the synthesis of the heavy chain of ferritin, suggesting that TNF may be involved in iron homeostasis (Torti et al. (1988) J. Biol. Chem. 263, 12638-12644). The experiments reported here demonstrate that in cultured human muscle cells, IL-1 induces ferritin H mRNA and protein as effectively as TNF. TNF and IL-1 were additive in their effects on ferritin H expression, and IL-1 induction of ferritin H was not blocked by anti-TNF antibodies. Ferritin H induction was a specific response not observed with beta or gamma interferon, nor with transforming growth factor beta. Both differentiated myotubes as well as myoblasts responded to IL-1 with the induction of ferritin H. These results suggest that monokine-mediated alterations in the subunit composition of the ferritin molecule may be of biological relevance in the response to inflammation and injury.     

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.     

Overexpression of H ferritin and up-regulation of iron regulatory protein genes during differentiation of 3T3-L1 pre-adipocytes

The role of iron-dependent oxidative metabolism in protecting the oxidable substrates contained in mature adipocytes is still unclear. Because differentiation increases ferritin formation in several cell types, thereby leading to an accumulation of H-rich isoferritins, we investigated whether differentiation affects iron metabolism in 3T3-L1 pre-adipocytes. To this aim, we evaluated the expression of the genes coding for the H and L ferritin subunits and for cytoplasmic iron regulatory protein (IRP) during the differentiation of 3T3-L1 cells in adipocytes induced by the addition of isobutylmethylxanthine, insulin, and dexamethasone. Differentiation enhanced ferritin formation and caused overexpression of the H subunit, thus altering the H/L subunit ratio. Northern blot analysis showed increased levels of H subunit mRNA. A gel retardation assay of cytoplasmic extract from differentiated cells, using an iron-responsive element as a probe, revealed enhanced an RNA binding capacity of IRP1, which correlated with the increase of IRP1 mRNA. The observed correlation between differentiation and iron metabolism in adipocytes suggests that an accumulation of H-rich isoferritin may limit the toxicity of iron in adipose tissue, thus exerting an antioxidant function.     

Multiple red cell ferritin mRNAs, which code for an abundant protein in the embryonic cell type, analyzed by cDNA sequence and by primer extension of the 5'-untranslated regions

Ferritin maintains iron in a bioavailable, nontoxic form for vertebrates and invertebrates, higher plants, fungi, and bacteria; the protein is formed from two classes of subunits (H and L) in ratios which vary in different cell types. Ferritin may be an abundant, differentiation-specific protein or a "housekeeping" protein. The red cells of embryos are specialized for iron storage and have abundant ferritin; iron regulates the synthesis of ferritin in such cells translationally by recruitment of stored, ferritin mRNA and by translational competition. To characterize mRNA regulated in such a manner, we prepared cDNA from reticulocytes of bullfrog tadpoles, a readily available source of embryonic red cells; moreover, no protein sequence information was available for nonmammalian ferritin. An almost full-length (817 base pairs) cDNA (pJD5F12) was isolated and sequenced, the 5' end was analyzed by primer extension, and the cloned DNA was used as a hybridization probe. We have shown that ferritin mRNA is stored in the cytoplasm and that the 5' end of the mRNA is heterogeneous. The 5'-untranslated region of ferritin mRNA consisted of 143 nucleotides in the major (65%) species and 146 or 152 in the minor species (approximately 17% each). (Heterogeneity is characteristic of some other abundant mRNAs, e.g. globin, which is also translationally regulated.) Since excess iron had no detectable effect on the heterogeneity of the 5' end of ferritin mRNA, the feature is more likely associated with mRNA abundance and/or cell specialization than translational control. In the bullfrog, as in humans and rats, ferritin is encoded by multiple genomic sequences (four to eight) which specify proteins of considerable homology. For example, 75 of the 81 amino acids present in all mammalian ferritins sequenced are also present in the frog; the overall homology between frogs and humans or rats is 59-66%. Ferritin H and L subunits in humans are distinct (overall homology 56%) and appear to have diverged from a common precursor relatively recently. In contrast, ferritin H and L subunits have high homology in tadpole red cells, determined by hybrid select translation, which suggests that bullfrog red cell ferritin may be close to the primordial sequence.     

Two ferritin subunits from disk abalone (Haliotis discus discus): cloning, characterization and expression analysis

Ferritin plays a key role in cellular iron metabolism, which includes iron storage and detoxification. From disk abalone, Haliotis discus discus, the cDNA that encodes the two ferritin subunits abalone ferritin subunit 1 (Abf1) and abalone ferritin subunit 2 (Abf2) were cloned. The complete cDNA coding sequences for Abf1 and Abf2 contained 621 and 549 bp, encoding for 207 and 183 amino acid residues, respectively. The H. discus discus Abf2 subunit contained a highly conserved motif for the ferroxidase center, which consists of seven residues of a typical vertebrate heavy-chain ferritin with a typical stem-loop structure. Abf2 mRNA contains a 27 bp iron-responsive element (IRE) in the 5'UTR position. This IRE exhibited 96% similarity with pearl and Pacific oyster and 67% similarity with human H type IREs. However, the Abf1 subunit had neither ferroxidase center residues nor the IRE motif sequence; instead, it contained iron-binding region signature 2 (IBRS) residues. Recombinant Abf1 and Abf2 proteins were purified and the respective sizes were about 24 and 21 kDa. Abf1 and Abf2 exhibited iron-chelating activity 44.2% and 22.0%, respectively, at protein concentration of 6 microg/ml. Analysis of tissue-specific expression by RT-PCR revealed that Abf1 and Abf2 ferritin mRNAs were expressed in various abalone tissues, such as gill, mantle, gonad, foot and digestive tract in a wide distribution profile, but Abf2 expression was more prominent than Abf1.     

中华鲟铁蛋白基因cDNA全长克隆与组织表达分析

根据铁蛋白基因的保守序列,搜索GenBank数据库中华鲟的EST数据库得到一条同源序列.通过RT-PCR的方法对该序列进行扩增,修改其测序错误,获得中华鲟铁蛋白亚基cDNA全长,经过注释提交GenBank数据库,获取序列登录号EU348782.该cDNA长度为896bp,包含531bp的完整编码区,推测编码的蛋白质为176aa,分子量为20339.9Mr,理论等电点为5.66.它和大两洋鲑鱼铁蛋白序列同源性最高,达到82.9%.该基闪在中华鲟肝脏、胰脏、肌肉、脑、心脏、鳃和胃粘膜等多种组织表达,在胰脏和心脏中表达量较高,在肌肉组织中表达较低.根据同源模建的方法得到该蛋白质三维结构,其包括5个α螺旋和10个转角结构,和人、蛙和细菌的铁蛋白均能很好的叠合,表现了很高的相似性,表明该蛋白结构和功能在基因进化中的高度保守性.     

Cloning and expression of 32 kDa ferritin from Galleria mellonella

We have sequenced a cDNA clone encoding 32-kDa ferritin subunit in the Wax Moth, Galleria mellonella. The 32-kDa ferritin subunit cDNA was obtained from PCR using identical primer designed from highly conserved regions of insect ferritins. RACE PCR was used to obtain the complete protein coding sequence. The 32-kDa ferritin subunit encoded a 232 amino acid polypeptide, containing a 19 leader peptide. The iron-responsive element (IRE) sequence with a predicted stem-loop structure was present in the 5'-untranslated region of the wax moth 32-kDa ferritin subunit mRNA. The 32-kDa sequence alignment had 78 and 69% identity with Manduca sexta and Calpodes ethlius (G), respectively. The G. mellonella ferritin subunits showed minimal identity with each other (19%). The glycosylation site (Asn-X-Ser/Thr) was found in the 32-kDa subunit but not in the 26-kDa subunit. Northern blot analysis showed that the mRNA expression of the 32-kDa ferritin was detected in the fat body and midgut. The fat body expression increased after 6 h and the mRNA in midgut dramatically increased about 3-fold the expression level at 12 h after iron feeding. Western blot revealed that a protein level of the 32-kDa subunit is abundant in midgut after 12 and 24 h iron feeding.     

Purification of a specific repressor of ferritin mRNA translation from rabbit liver

The synthesis of ferritin is regulated at the translation level in coordination with iron availability. Under conditions of low iron, translation of ferritin mRNA is repressed and the majority of ferritin mRNA is non-polysomal. Upon an increase in iron, translation of ferritin mRNA is derepressed resulting in as much as a 50-100-fold increase in the rate of ferritin synthesis. This regulation is mediated at least in part by a specific translational repressor which binds to a conserved sequence, the iron responsive element, located in the 5'-untranslated region of ferritin mRNA. In this communication we report the purification of such a repressor from rabbit liver. This repressor, which we call the "ferritin repressor protein," has an apparent molecular mass of 90 kDa when analyzed by gel filtration chromatography. It inhibits translation of ferritin mRNA in a highly specific fashion when added to a wheat germ lysate programmed with liver poly(A+) mRNA. In addition, it binds specifically to sequences contained within the first 92 nucleotides of ferritin mRNA, most likely the iron responsive element. Analysis of highly purified repressor by sodium dodecyl sulfate-polyacrylamide gel electrophoresis shows that it is composed primarily of a single polypeptide of approximately 90 kDa. Elution of this 90-kDa polypeptide from a sodium dodecyl sulfate gel followed by renaturation and analysis for repressor activity shows that it both binds to the 5'-untranslated region of ferritin mRNA and represses its translation in vitro.     

Cloning, sequencing, and expression of cDNA for human beta-galactosidase

We cloned and sequenced the full-length cDNA for human placental beta-galactosidase. The 2379-nucleotide sequence contains 2031 nucleotides which encode a protein of 677 amino acids. The amino acid sequence includes a putative signal sequence of 23 amino acids and 7 potential asparagine-linked glycosylation sites. The cDNA in the expression vector pSVL was used to transfect COS cells. Expression of the cDNA in transfected COS cells produced immunoprecipitable proteins and led to an increase in beta-galactosidase activity.     

Hyphantria cunea ferritin heavy chain homologue: cDNA sequence and mRNA expression

We have sequenced a cDNA clone encoding a 26-kDa ferritin subunit, which was heavy chain homologue (HCH), in fall webworm, Hyphantria cunea. The HCH cDNA was obtained from the screening of a cDNA library using a PCR product. H. cunea ferritin is composed of 221 amino acid residues and their calculated mass is 26,160 Da. The protein contains the conserved motifs for the ferroxidase center typical for heavy chains of vertebrate ferritin. The iron-responsive element sequence with a predicted stem-loop structure is present in the 5'-untranslated region of ferritin HCH mRNA. The sequence alignment of ferritin HCH shows 68.9 and 68.7% identity with Galleria mellonella HCH (26 kDa ferritin) and Manduca sexta HCH, respectively. While G type insect ferritin vertebrate light chain homologue (LCH) is distantly related to H. cunea ferritin HCH (17.2-20.8%), the Northern blot analysis revealed that H. cunea ferritin HCH was ubiquitously expressed in various tissues and all developmental stages. The ferritin expression of midgut is more responsive to iron-fed, compared to fat body in H. cunea.     

Sequence of cDNAs for mammalian H2A.Z, an evolutionarily diverged but highly conserved basal histone H2A isoprotein species.

The nucleotide sequences of cDNAs for the evolutionarily diverged but highly conserved basal H2A isoprotein, H2A.Z, have been determined for the rat, cow, and human. As a basal histone, H2A.Z is synthesized throughout the cell cycle at a constant rate, unlinked to DNA replication, and at a much lower rate in quiescent cells. Each of the cDNA isolates encodes the entire H2A.Z polypeptide. The human isolate is about 1.0 kilobases long. It contains a coding region of 387 nucleotides flanked by 106 nucleotides of 5'UTR and 376 nucleotides of 3'UTR, which contains a polyadenylation signal followed by a poly A tail. The bovine and rat cDNAs have 97 and 94% nucleotide positional identity to the human cDNA in the coding region and 98% in the proximal 376 nucleotides of the 3'UTR which includes the polyadenylation signal. A potential stem-forming sequence imbedded in a direct repeat is found centered at 261 nucleotides into the 3'UTR. Each of the cDNA clones could be transcribed and translated in vitro to yield H2A.Z protein. The mammalian H2A.Z cDNA coding sequences are approximately 80% similar to those in chicken and 75% to those in sea urchin.