Cloning of bovine prolactin cDNA and evolutionary implications of its sequence

Prolactin, growth hormone, and chorionic somatomammotropin (placental lactogen) constitute a set of related polypeptides believed to derive from a common evolutionary ancestor protein. We have cloned and sequenced DNA complementary to the mRNA coding for bovine prolactin. This cDNA contains 702 bases corresponding to 10 amino acids in the leader peptide, all 199 amino acids of the hormone, and 75 nucleotides in the 3' untranslated region of the mRNA. Nucleotide sequence analysis of this cDNA permitted the identification of 10 amino acids in the signal peptide, plus the correction or elucidation of amino acid assignments at 16 sites where aspartic and glutamic acids had not been distinguished from their amides by amino acid sequencing. Codon usage in bovine prolactin mRNA is nonrandom, but, similarly to rat and human prolactins, it does not exhibit the strong preference for G or C in codon third positions seen in bovine, rat, and human growth hormone mRNAs. The translational termination signal in bovine prolactin in UAA, also the same as in rat and human prolactins and differing from the UAG "stop" codon used in bovine, rat, and human growth hormones and human chorionic somatomammotropin. The amino acid and mRNA nucleotide sequences of bovine, rat, and human prolactins and growth hormones were compared by several techniques based on various theories of molecular evolution. The comparison of prolactin to growth hormone is consistent in all three species, suggesting that the genes for these two hormones diverged about 350 million years ago. However, comparisons among the three prolactins or among the three growth hormones to determine the times of evolutionary divergence of the three species generated values that were inconsistent with each other and with the fossil record. Analysis of these discrepancies suggests that the genes for prolactin and growth hormone may now be evolving by different mechanisms

Selective and Signal-dependent Recruitment of Membrane Proteins to Secretory Granules Formed by Heterologously Expressed von Willebrand Factor

von Willebrand factor (vWF) is a large, multimeric protein secreted by endothelial cells and involved in hemostasis. When expressed in AtT-20 cells, vWF leads to the de novo formation of cigar-shaped organelles similar in appearance to the Weibel-Palade bodies of endothelial cells in which vWF is normally stored before regulated secretion. The membranes of this vWF-induced organelle, termed the pseudogranule, are uncharacterized. We have examined the ability of these pseudogranules, which we show are secretagogue responsive, to recruit membrane proteins. Coexpression experiments show that the Weibel-Palade body proteins P-selectin and CD63, as well as the secretory organelle membrane proteins vesicle-associated membrane protein-2 and synaptotagmin I are diverted away from the endogenous adrenocorticotropic hormone-containing secretory granules to the vWF-containing pseudogranules. However, transferrin receptor, lysosomal-associated membrane protein 1, and sialyl transferase are not recruited. The recruitment of P-selectin is dependent on a tyrosine-based motif within its cytoplasmic domain. Our data show that vWF pseudogranules specifically recruit a subset of membrane proteins, and that in a process explicitly driven by the pseudogranule content (i.e., vWF), the active recruitment of at least one component of the pseudogranule membrane (i.e., P-selectin) is dependent on residues of P-selectin that are cytosolic and therefore unable to directly interact with vWF