Genetic engineering of peptide hormones. II. Possible polymorphism of bovine preprolactin. Molecular cloning data

The primary structure of an insert from a clone isolated from the bovine pituitary cDNA library by hybridization with prolactin-specific probe has been determined. It was found that the rearrangement of cDNA took place in the process of cloning. The rearrangement includes the inversion of 5'-terminal and the deletion of the central part of cDNA. However from the structure of the insert we were able to deduce the sequences of 5'- and 3'-terminal regions of bovine preprolactin mRNA (257 and 551 bases long). The comparison of these sequences with those published earlier revealed several differences in the primary structure. The most essential of them is the additional triplet coding for alanine in position of -22 of the signal peptide. The heterogeneity of bovine preprolactin mRNA in the region coding for the signal peptide is considered to be a consequence of alternative splicing as it was shown for rat preprolactin mRNA.     

Estrogen induced prolactin mRNA accumulation in adult male rat pituitary as revealed by in situ hybridization

Adult male rats were injected with different doses (1, 10, and 100 micrograms) of 17 beta-estradiol daily for 5 days, and the changes in prolactin (PRL) mRNA levels were examined by in situ hybridization and cytoplasmic dot blot hybridization using cloned cDNA for rat prolactin mRNA. An increase in cytoplasmic PRL mRNA content was evident in all the animals treated with estrogen as revealed with cytoplasmic dot blot analysis. There were however, no significant differences in PRL mRNA content among the three estradiol treated groups. Cytoplasmic PRL mRNA was also demonstrated by in situ hybridization on the frozen pituitary sections using a 3H-labeled PRL cDNA probe. The number of grains per cell was increased after estrogen treatment. 3H-thymidine uptake into pituitary cells was also examined in vivo using combined techniques of immunocytochemistry and autoradiography. Although the percentage of immunoreactive PRL cells which took up thymidine in their nuclei increased to more than double after estrogen treatment, the increase in the total number of immunoreactive PRL cells was small. These results suggest that the major effect of estrogen on PRL cells is an increase in the accumulation of PRL mRNA in the individual PRL cells. The number of grains per cell was found to vary from cell to cell, both in control and estrogen treated animals. This variability is discussed in relation to the functional heterogeneity within the PRL cell population.     

Molecular cloning and nucleotide sequence analysis of complementary deoxyribonucleic acid for the beta-subunit of rat follicle stimulating hormone

To provide a hybridization probe for analysis of the regulation of rat gonadotropin subunit mRNA levels, an effort was made to isolate a cloned cDNA for the beta-subunit of rat FSH (FSH beta). Using a cloned bovine FSH beta cDNA as a hybridization probe, a rat pituitary lambda gt10 cDNA library was screened and a single, strongly hybridizing clone identified. The 874 base pair cDNA insert from this clone contains the complete sequence of rat FSH beta including an amino-terminal precursor segment. Hybridization of this cloned cDNA to rat pituitary RNA demonstrated the presence of an approximately 2.0 kilobase RNA species containing FSH beta sequences. Cloned rat cDNA was also used to demonstrate that estrogen treatment of ovariectomized female rats results in decreases in mRNA concentrations for FSH beta and the beta-subunit of LH with somewhat smaller decreases in alpha-subunit mRNA concentrations. Little or no change was detected in the mRNA for the beta-subunit of TSH.     

Regulation of ornithine aminotransferase mRNA levels in rat kidney by estrogen and thyroid hormone

The regulation of the mitochondrial matrix enzyme, ornithine aminotransferase, by estrogen and triiodothyronine (T3) in rat kidney was examined using a cloned cDNA probe and in vitro translation of poly(A+) RNA. After a single, acute dose of either 17 beta-estradiol or T3, the rate of enzyme synthesis and the levels of translatable and hybridizable ornithine aminotransferase mRNA all increase in parallel. Levels of hybridizable mRNA were estimated by hybridization of randomly 32P-labeled RNA to filter-bound plasmid DNA. Maximal levels of induction by estrogen and T3 were about 15- and 3-fold, respectively. Lag times of at least 5 h and less than 3 h were observed for induction by T3 and estrogen. T3 and estrogen exert a synergistic effect in increasing ornithine aminotransferase mRNA levels. 16 h after T3 administration and 24 h after estrogen administration, a 1.6- and 13-fold increase in mRNA levels were observed. Both of these treatments in combination for the indicated time periods resulted in a 21-fold increase in ornithine aminotransferase mRNA. From the mRNA accumulation curves, half-lives of 10 to 14 h and 12 to 16 h were estimated for the mRNA after estrogen and T3 induction, respectively. These similar half-lives suggest that an increase in the rate of mRNA production is primarily responsible for the induction observed after estrogen administration.     

Structure of the rat prolactin gene

The organization and sequence of the rat preprolactin gene has been investigated. Analysis of two different plasmids containing pituitary cDNA inserts has provided the complete 681-nucleotide coding sequence of preprolactin as well as 17 nucleotides preceding the initiation codon and 90 nucleotides following the termination codon. Digestion of rat chromosomal DNA with the restriction endonuclease Eco RI followed by size fractionation and hybridization to a labeled prolactin cDNA probe has demonstrated that prolactin genomic sequences are located on 6.0-, 3.9-, and 2.9-kilobase fragments. The 6.0- and 3.9-kilobase fragments were isolated from a library of cloned rat DNA fragments. The sequence of more than 1800 nucleotides of the cloned DNA has been determined. The sequenced region contains coding regions of 180 and 189 nucleotides which specify the COOH-terminal 123 amino acids of the 227-amino-acid sequence of rat preprolactin. These coding regions are separated by an intervening sequence of 597 nucleotides. At least one other large intervening sequence separates this region from the region coding for the NH2-terminal portion of preprolactin. Hybridization experiments suggested that the intervening sequences of the rat prolactin gene contain DNA sequences which are repeated elsewhere in the rat genome.     

Cloning and sequence analysis of cDNA for mouse prolactin

The present study was undertaken to find out whether or not sexual dimorphism in biological activities and amino acid compositions of mouse prolactin might be due to heterogeneity in mRNA for mouse prolactin Cloned cDNAs for mouse prolactin were first isolated from a mouse pituitary cDNA library by hybridization with a rat prolactin cDNA. Then, one clone of about 140 positive clones obtained from 2000 transformants was subjected to nucleotide sequence analysis and verified to contain a nearly full length of cDNA sequence coding for mouse prolactin precursor. The deduced complete amino acid sequence indicates that the precursor molecule consists of 31 amino acids as the signal peptide and 197 amino acids of prolactin, in which two amino acids were found to be different from the amino acid sequence previously published elsewhere. S1 nuclease mapping analysis using male and female pituitary RNAs indicates that mouse preprolactin is encoded by two mRNAs in both sexes. The two mRNAs differ from each other based upon the deletion of three nucleotides in the coding region for the signal peptide determined by the nucleotide sequence analysis in other cDNA clones. In the present study, no sexual difference was revealed in murine prolactin mRNA.     

Molecular cloning of cDNA corresponding to mRNA species whose steady state levels in the thyroid are enhanced by thyrotropin. Homology of one of these sequences with ferritin H

A lambda gt11 cDNA library was constructed using poly(A)+ mRNA from thyrotropin (TSH)-stimulated Fisher rat thyroid (FRTL5) cells. The library was screened for nonthyroglobulin cDNA sequences by differential plaque filter hybridization using single-stranded cDNA probes synthesized from mRNA prepared from quiescent and TSH-stimulated FRTL5 cells. Thyroglobulin cDNA-containing recombinants in the library were avoided by prehybridizing the TSH probe to excess thyroglobulin cDNA. Of 48,000 clones screened, 60 were chosen as representing mRNA species whose abundance was increased in TSH-stimulated versus quiescent cultures. Southern blot analysis of 9 clones confirmed that the TSH-cDNA probe hybridized to a greater extent to the cDNA inserts than did the control probe. cDNA insert sizes varied between 0.3 kilobase (kb) and 1.0 kb. Northern slot blot analysis using as probes the cDNA of four of these clones (FC4, FC26, FC29, and FC43) demonstrated that TSH stimulation of FRTL5 cells increased the steady state levels of the respective mRNA species by 4-12-fold. For all 4 clones, increases in mRNA levels were apparent within approximately 1 h and were maximal after 14-18 h of TSH stimulation. Determination of the partial nucleotide sequence of these 4 clones confirmed that none was thyroglobulin, thyroid peroxidase, or any other gene previously reported to be stimulated by TSH. Three of the clones bore no homology to any known nucleotide sequence, but FC26 was 85% homologous with human ferritin H. Northern blot analysis using the FC26 cDNA insert as a probe confirmed hybridization to an mRNA species of 1 kb, the known size of ferritin H mRNA. In summary, using the technique of differential plaque filter hybridization, we have identified 4 new genes whose mRNA levels are increased by TSH stimulation of thyroid cells. One of these genes is homologous to human ferritin H.