Ubiquitin is a heat shock protein in chicken embryo fibroblasts.

Clones containing heat-inducible mRNA sequences were selected from a cDNA library prepared from polyadenylated RNA isolated from heat-shocked chicken embryo fibroblasts. One recombinant DNA clone, designated clone 7, hybridized to a 1.2-kilobase RNA that was present in normal cells and increased fivefold during heat shock. Clone 7 also hybridized to an RNA species of 1.7 kilobases that was present exclusively in heat-shocked cells. In vitro translation of mRNA hybrid selected from clone 7 produced a protein product with a molecular weight of approximately 8,000. Increased synthesis of a protein of similar size was detected in chicken embryo fibroblasts after heat shock. DNA sequence analysis of clone 7 indicated its protein product has amino acid sequences identical to bovine ubiquitin. In addition, clone 7 contains tandem copies of the ubiquitin sequences contiguous to each other with no untranslated sequences between them. We discuss some possible roles for ubiquitin in the heat shock response.     

Isolation of a cDNA clone complementary to sequences for a 34-kilodalton protein which is a pp60v-src substrate.

We have isolated a partial cDNA clone containing sequences complementary to a mRNA encoding a 34- to 36-kilodalton normal chicken cell protein which is a substrate for pp60v-src kinase activity. Using this 34-kilodalton cDNA clone as a probe, we determined that the size of the 34-kilodalton mRNA was 1,100 nucleotides and the level of the 34-kilodalton RNA was the same in various tissues of mature chickens but was significantly higher in chicken embryo fibroblast cells.     

Isolation and characterization of a cDNA encoding a chick alpha-actinin

We have isolated and sequenced a 2.1-kilobase cDNA encoding 86% of the sequence of alpha-actinin. The cDNA clone was isolated from a chick embryo fibroblast cDNA library constructed in the expression vector lambda gt11. Identification of this sequence as alpha-actinin was confirmed by immunological methods and by comparing the deduced protein sequence with the sequence of several CNBr fragments obtained from adult chicken smooth muscle (gizzard) alpha-actinin. The deduced protein sequence shows two distinct domains, one of which consists of four repeats of approximately 120 amino acids. This region corresponds to a previously identified 50-kDa tryptic peptide involved in formation of the alpha-actinin dimer. The last 19 residues of C-terminal sequence display an homology with the so-called E-F hand of Ca2+-binding proteins. Hybridization analysis reveals only one size of mRNA (approximately 3.5 kilobases) in fibroblasts, but multiple bands in genomic cDNA.     

The nucleotide sequence of a complete chicken delta-crystallin cDNA

The nucleotide sequence of a full length cDNA of delta-crystallin mRNA from chicken lens has been determined using a delta-crystallin cDNA clone (pB delta 11), which represents the mRNA sequence of 1530 nucleotides from the poly(A) junction but does not contain the 5'-terminal sequence of 44 nucleotides of the mRNA. The 5'-terminal sequence of the mRNA, absent in the cDNA clone, has been determined with a stretch of cDNA sequence by the primer extension procedure. The amino acid sequence deduced from the nucleotide sequence is consistent with the amino acid sequences of several tryptic peptides, the total amino acid composition, and the mol. wt. of delta-crystallin estimated by SDS-polyacrylamide gel electrophoresis. The computer-assisted analysis predicts high alpha-helical content throughout the polypeptide. Sequence analyses have revealed that gene 1 encodes the mRNA from which the cDNA clone was derived.     

Transformation by the src oncogene alters glucose transport into rat and chicken cells by different mechanisms.

Transformation of both rat and chicken fibroblasts by the src oncogene leads to a four- to fivefold increase in the rate of glucose transport and in the level of the glucose transporter protein. We have previously shown that, with chicken embryo fibroblasts, transformation leads to a reduction in the rate of degradation of the transporter, with little or no increase in the rate of its biosynthesis. We now show that, with the rat-1 cell line, the opposite result was obtained. src-induced transformation led to an increase in transporter biosynthesis, with little effect on turnover. A src-induced increase in transporter mRNA entirely accounted for the increase in biosynthesis of the protein. By contrast, in chicken embryo fibroblasts, the level of transporter mRNA was low and was not induced to rise by src transformation. Thus, src induced an increase in the level of the glucose transport protein by fundamentally different mechanisms in chicken embryo fibroblasts and rat-1 cells. To test whether this difference was due to rat-1 cells being an immortalized cell line, we measured transporter mRNA levels in primary fibroblast cultures from rat embryos and in parallel cultures transformed by src. Transporter mRNA was inducible by src in these cells. Thus, the difference in mRNA inducibility between chicken and rat cells is not due to immortalization.     

Differential regulation of glucose transporter isoforms by the src oncogene in chicken embryo fibroblasts.

The increase in glucose transport that occurs when chicken embryo fibroblasts (CEFs) are transformed by src is associated with an increase in the amount of type 1 glucose transporter protein, and we have previously shown that this effect is due to a decrease in the degradation rate of this protein. The rate of CEF type 1 glucose transporter biosynthesis and the level of its mRNA are unaffected by src transformation. To study the molecular basis of this phenomenon, we have been isolating chicken glucose transporter cDNAs by hybridization to a rat type 1 glucose transporter probe at low stringency. Surprisingly, these clones corresponded to a message encoding a protein which has most sequence similarity to the human type 3 glucose transporter and which we refer to as CEF-GT3. CEF-GT3 is clearly distinct from the CEF type 1 transporter that we have previously described. Northern (RNA) analysis of CEF RNA with CEF-GT3 cDNA revealed two messages of 1.7 and 3.3 kb which were both greatly induced by src transformation. When the CEF-GT3 cDNA was expressed in rat fibroblasts, a three-to fourfold enhancement of 2-deoxyglucose uptake was observed, indicating that CEF-GT3 is a functional glucose transporter. Northern analyses using a CEF-GT3 and a rat type 1 probe demonstrated that there is no hybridization between different isoforms but that there is cross-species hybridization between the rat type 1 probe and the chicken homolog. Southern blot analyses confirmed that the chicken genomic type 1 and type 3 transporters are encoded by distinct genes. We conclude that CEFs express two types of transporter, type 1 (which we have previously reported to be regulated posttranslationally by src) and a novel type 3 isoform which, unlike type 1, shows mRNA induction upon src transformation. We conclude that src regulates glucose transport in CEFs simultaneously by two different mechanisms.     

Molecular cloning and sequence analysis of a chicken ornithine decarboxylase cDNA

A chicken embryo cDNA library was screened with a mouse probe for ornithine decarboxylase (ODC) and 14 positively hybridizing clones isolated. The longest of these (1.7 kb) was sub-cloned and sequenced. It is estimated that the clone comprises approximately 98% of the coding region for chicken ODC. The DNA sequence shows 78% identity with the human ODC cDNA sequence and the deduced amino acid sequence is almost 90% homologous to mouse and human. Both the peptide and cDNA sequences show interesting potential regulatory features which are discussed here.     

Structure, evolution, and regulation of chicken apolipoprotein A-I

A full-length cDNA clone for the precursor form of chicken liver apolipoprotein A-I (apoA-I) was isolated by antibody screening of a chicken liver cDNA library in the expression vector lambda gt11. The complete nucleotide sequence and predicted amino acid sequence of this clone is presented. The identity of the clone was confirmed by comparison with partial amino acid sequences for chicken apolipoprotein A-I. Chicken preproapolipoprotein A-1 consists of an 18-amino acid prepeptide, a 6-amino acid propeptide, and 240 amino acids of mature protein. The sequence of the protein is homologous to mammalian apoA-I and is highly internally repetitive, consisting largely of 11-amino acid repeats predicted to have an amphipathic alpha-helical structure. The sequence of the propeptide (Arg-Ser-Phe-Trp-Gln-His) differs in two positions from that of mammalian apoA-I. The mRNA for chicken apoA-I is about 1 kilobase in length and is expressed in a variety of tissues including liver, intestine, brain, adrenals, kidneys, heart, and muscle. This quantitative tissue distribution has been determined and is similar to that observed for mammalian apoE and different from that of mammalian apoA-I mRNA. This reinforces the concept that avian apoA-I performs functions analogous to those of mammalian apoE. Moreover, comparisons revealed sequences of chicken apoA-I similar to the region of mammalian apoE responsible for interaction with cellular receptors. Previous studies have demonstrated striking changes in the rates of synthesis of apoA-I in breast muscle during development and in optic nerve after retinal ablation. We now demonstrate that these changes are paralleled by changes in mRNA levels. ApoA-I mRNA levels increase approximately 50-fold in breast muscle between 14 days postconception and hatching and then decrease about 15-fold to adult levels. The levels of apoA-I mRNA increase about 3-fold in optic nerve following retinal ablation. ApoA-I mRNA is also found in the brain in the absence of nerve injury. This may indicate that locally synthesized apoA-I has a routine or housekeeping function in lipid metabolism in the central nervous system.     

Molecular cloning and the nucleotide sequence of cDNA for embryonic chicken pepsinogen: phylogenetic relationship with prochymosin

Embryonic chicken pepsinogen is an aspartyl proteinase that is specifically secreted during the embryonic period in the chicken proventriculus (glandular stomach). To learn the phylogeny of this pepsinogen, we isolated a cDNA clone by screening a lambda gt11 library of embryonic proventricular cDNAs with an antiserum to the embryonic chicken pepsinogen. We obtained a 200-base pair cDNA clone which encoded 18 amino acids that had high sequence homology with the carboxyl termini of other pepsinogens. Northern blot analysis revealed that this cDNA clone hybridized to a mRNA of 1,600 bases in the embryonic proventriculus but not to the mRNA in the adult proventriculus. The almost complete nucleotide sequence of embryonic chicken pepsinogen-cDNA was determined by sequencing longer cDNAs obtained by screening the same library with the 200-base pair cDNA and primer extension with a synthetic primer. The cDNA consisted of 1,281 nucleotides and encoded 383 amino acids for prepepsinogen. The predicted amino acid sequence was compared with the sequences of other aspartyl proteinases: pepsinogen A of human, monkey, pig, and chicken, progastricsin of monkey and rat, and bovine prochymosin. The phylogenetic tree constructed for them indicates the possibility that embryonic chicken pepsinogen diverged from prochymosin, after prochymosin and pepsinogen A had diverged from each other.     

A chicken mRNA similar to heterogeneous nuclear ribonucleoprotein H1

Heterogeneous nuclear ribonucleoproteins are predominantly nuclear RNA-binding proteins that function in a variety of cellular activities. The objective of these experiments was to clone a cDNA for a chicken protein similar to other previously reported heterogeneous ribonucleoproteins for other species. The 5' and 3' ends of the chicken mRNA were cloned using Rapid Amplification of cDNA Ends (RACE). Subsequently, the expression of the mRNA sequence was confirmed via Northern analysis. The deduced amino acid sequence was approximately 86% identical to corresponding regions of human, mouse, or zebrafish proteins similar to heterogeneous nuclear ribonucleoprotein H1. The expression data confirmed the size of the predicted mRNA sequence. The newly identified sequence may be employed in future studies aimed at understanding the role of heterogeneous nuclear ribonucleoproteins in avian species.     

Glyceraldehyde 3-phosphate dehydrogenase protein and mRNA are both differentially expressed in adult chickens but not chick embryos

We have determined the 679 nucleotide sequence of a cDNA clone which, by hybridization-translation experiments, corresponds to a 36K chick brain protein. Our studies provide a partial amino acid sequence for this protein, identifying it as chicken glyceraldehyde-3-phosphate dehydrogenase (GAPDH). Antisera raised against purified chicken GAPDH reacted with a 36K protein present in chick brain extracts and estimated to be the fourth most prevalent protein, as determined by either Coomassie Blue staining or by in vitro translation of chick brain mRNA. The amounts of GAPDH mRNA in chick brain, liver and muscle and adult chicken brain are similar, whereas the relative amount of adult chicken muscle GPDH mRNA is greatly elevated and that of adult liver lowered. The GAPDH protein levels showed a similar variation between tissues, suggesting that the levels of GAPDH protein are largely regulated by the amount of available GAPDH mRNA. The chicken GAPDH clone does not hybridize to rat mRNA, even though GAPDH is one of the most evolutionarily conserved proteins, indicating that selection pressures are heavier at the primary protein sequence level than at the nucleic acid sequence level for this gene, a situation contrasting to that of the tubulins.     

Molecular cloning of chicken metallothionein. Deduction of the complete amino acid sequence and analysis of expression using cloned cDNA.

A cDNA library was constructed using RNA isolated from the livers of chickens which had been treated with zinc. This library was screened with a RNA probe complementary to mouse metallothionein-I (MT), and eight chicken MT cDNA clones were obtained. All of the cDNA clones contained nucleotide sequences homologous to regions of the longest (376 bp) cDNA clone. The latter contained an open reading frame of 189 bp, and the deduced amino acid sequence indicates a protein of 63 amino acids of which 20 are cysteine residues. Amino acid composition and partial amino acid sequence analyses of purified chicken MT protein agreed with the amino acid composition and sequence deduced from the cloned cDNA. Amino acid sequence comparisons establish that chicken MT shares extensive homology with mammalian MTs, but is more closely related to the MT-II than to the MT-I isoforms from various mammals. The nucleotide sequence of the coding region of chicken MT shares approximately 70% homology with the consensus sequence for the mammalian MTs. Southern blot analysis of chicken DNA indicates that the chicken MT gene is not a part of a large family of related sequences, but rather is likely to be a unique gene sequence. In the chicken liver, levels of chicken MT mRNA were rapidly induced by metals (Cd2+, Zn2+, Cu2+), glucocorticoids and lipopolysaccharide. MT mRNA was present in low levels in embryonic liver and increased to high levels during the first week after hatching before decreasing again to the basal levels found in adult liver. The results of this study establish that MT is highly conserved between birds and mammals and is regulated in the chicken by agents which also regulate expression of mammalian MT genes. However, in contrast to the mammals, the results suggest the existence of a single isoform of MT in the chicken.