The primary structure of chicken liver cytochrome b5 deduced from the DNA sequence of a cDNA clone

Retention of cytochrome b5 in the endoplasmic reticulum is transmembrane and luminal domain-dependent

Cytochrome b5 (b5), a typical tail-anchored protein of the endoplasmic reticulum (ER) membrane, is composed of three functionally different domains: amino-terminal heme-containing catalytic, central hydrophobic membrane-anchoring, and carboxyl-terminal ER-targeting domains (Mitoma, J., and Ito, A. (1992) EMBO J. 11, 4197-4203). To analyze the potential retention signal of b5, mutant proteins were prepared to replace each domain with natural or artificial sequences, and subcellular localizations were examined using immunofluorescence microscopy and cell fractionation. The transmembrane domain functioned to retain the cytochrome in the ER, and the mutation of all or part of the transmembrane domain with an artificial hydrophobic sequence had practically no effect on intracellular distribution of the cytochrome. However, when the transmembrane domain was extended systematically, a substantial portion of the protein with the domain of over 22 amino acid residues leaked from the organelle. Thus, the transmembrane length functions as the retention signal. When cytochromes with mutations at the carboxyl-terminal end were overexpressed in cells, a substantial portion of the protein was transported to the plasma membrane, indicating that the carboxyl-terminal luminal domain also has a role in retention of b5 in the ER. Carbohydrate moiety of the glycosylatably-mutated b5 was sensitive to endoglycosidase H but resistant to endoglycosidase D. Therefore, both transmembrane and carboxyl-terminal portions seems to function as the static retention signal.

The isolation and characterization of the soluble and membrane-bound porcine cytochrome b5 cDNAs

In some male pigs, there is an increased production of the testicular 16 androstene steroids which end up being concentrated in fatty tissue. When the meat is cooked, a disagreeable odor/flavor is produced, a phenomenon known as "boar taint." All boars selected for food production are castrated even though only ca 10% of boars may be "tainted." This has a high economic cost because castrated pigs convert food into meat less efficiently, the meat is fatter, and there is an increased mortality due to the castration procedure. Recent data has implicated an increased level of cytochrome b5 in the testes with the increased synthesis of the 16-androstene steroids. As an initial step in analyzing this process, we used 5' and 3' RACE PCR procedures to isolate, clone and sequence the cDNAs for the membrane-bound and soluble forms of porcine cytochrome b5.

Soluble and membrane-bound forms of cytochrome b5 are the products of a single gene in chicken

In order to determine the relationship of the soluble cytochrome b5 found in erythrocytes to the membrane-bound form found in other tissues, a cDNA clone encoding cytochrome b5 in chicken erythrocytes was isolated by using mixed oligonucleotides based on a partial amino acid sequence of the protein. Complete nucleotide sequence identity between the erythrocyte cDNA and the sequence of a cDNA clone of the liver protein suggests that they are transcribed from the same gene. The isolation and structural analysis of genomic clones was also consistent with the presence of only one cytochrome b5 gene in chicken. These results suggest that the formation of soluble erythrocyte cytochrome b5 occurs by proteolytic processing of the membrane-bound form. Thus, previous reports indicating that the carboxyl terminal amino acid residue of the erythrocyte form differs from the corresponding residue of the membrane-bound form may suggest the existence of a novel post-translational modification.

Isolation and characterization of human liver cytochrome b5 cDNA

Three cDNA clones encoding human cytochrome b5 have been isolated and sequenced from a lambda gt 11 cDNA library of a human liver. The largest clone (b5-C) contains 765 base pairs corresponding to a complete coding sequence of 134 amino acids and sequences for 5' non-coding (56 bases) and 3' non-coding regions (307 bases). In Northern blots, a band hybridizing to 32P-labelled b5-B cDNA clone was detected at around 12S in mRNA of human and rat livers. The deduced amino acid sequence was identical with the partial amino acid sequence (2-100th) previously reported, except that two amino acid replacements were observed between the 89th and 91st positions. The deduced amino acid sequence of human cytochrome b5 shares 88.0, 86.5, 86.5 and 74.4% similarity with those of rat, pig, horse and chicken, respectively. The sequences in the haem binding region were highly conserved among these species. In addition, high similarities in the hydrophobicity profiles were maintained throughout their entire regions, although some diversity was observed in the N-terminal sequences between human and chicken.

The characterization of three types of partially processed mRNA and two pseudogenes for human liver cytochrome b5

We have isolated cDNA clones corresponding to partially processed human liver cytochrome b5 mRNAs. All the clones contained poly(A) sequences, and one clone had a shorter 3' non-translated sequence, indicating the use of an alternative poly(A) addition signal. In addition, all the clones contained the coding information for amino acids 87-134; however, there were two types of intron junction adjacent to the coding sequence. Detailed analysis of the Type I clones showed that the Type II intron sequence was contained within the Type I sequence, but approximately 1000 bp 5' of the Type I intron-exon junction showed alternative splicing within this intron. In addition, we have isolated two pseudogenes which lack introns, suggesting the retroviral insertion of human liver cytochrome b5 mRNA sequences into the human genome.

The complete nucleotide sequence of human liver cytochrome b5 mRNA

We have isolated and sequenced a cDNA clone corresponding to human liver cytochrome b5 mRNA. The 760 base pair (bp) sequence contains the complete coding and 3' non-translated regions plus 52 bp of 5' non-translated sequence. The derived amino acid sequence showed that the previous assignment of several amino acids was in error. In addition, the sequence of the previously unknown COOH hydrophobic region has been obtained.