Nucleotide sequence and growth hormone-regulated expression of salmon insulin-like growth factor I mRNA

Protein and cDNA sequence analysis have revealed that the insulin-like growth factor (IGF-I) has been highly conserved among several mammalian species. Using the combined techniques of polymerase chain reaction and molecular cloning, we have now obtained the cDNA sequence encoding preproIGF-I from a teleost species, Oncorhynchus kisutch (coho salmon). The 2020 nucleotide (nt) cloned cDNA sequence contains a 528 nt open reading frame encoding 176 amino acids in preproIGF-I and 175 nt and 1317 nt of flanking 5'- and 3'-untranslated regions, respectively. The deduced amino acid sequence of salmon IGF-I is highly conserved relative to its mammalian homologues and there are only 14 amino acid differences out of 70 between salmon and human IGF-I. Interestingly, the C-terminal E domain of salmon proIGF-I, which is presumed to be proteolytically cleaved during biosynthesis, also shows striking amino acid sequence homology with its mammalian counterpart, except for an internal 27 residue segment that is unique to salmon proIGF-I. Northern analysis revealed that salmon preproIGF-I mRNA consists predominantly of a single 3900 nt sized band although minor bands were also observed after prolonged autoradiographic exposure. The RNA analysis also revealed that the level of preproIGF-I mRNA is increased 6-fold in liver RNA isolated from salmon injected with bovine GH, as compared to untreated controls. These results demonstrate that the primary structure and regulated expression of IGF-I by GH have been conserved in teleosts.

Expression of five cathepsins in murine melanomas of varying metastatic potential and normal tissues

The relative levels of mRNAs for cathepsins B, D, H, L, and S in eight normal murine tissues and three murine melanoma variants, B16-F1, B16-F10, and B16a, have been analyzed by RNA dot blot and densitometry. A direct correlation was observed between the levels of cathepsin B mRNA and the metastatic potentials of these three melanoma variants. The relative amount of cathepsin B mRNA in B16a, which is the melanoma variant with the highest metastatic potential, was at least 3 times greater than that found in any of the normal murine tissues surveyed. Similar results were obtained in analyses of either solid tumors or of cultures of tumor cells, confirming that the tumor cells themselves were the source for the elevated expression of cathepsin B mRNA. Northern blot analysis revealed the presence of three cathepsin B transcripts of 5.0, 4.0, and 2.2 kilobases in the melanoma variants, while only the 2.2-kilobase transcript was seen in the normal murine tissues. Concurrently with the mRNA analysis, enzyme assays for cathepsin B activity were also performed using synthetic peptide substrates. The assays revealed increased cathepsin B activities in the melanoma variants, corresponding well with the increased cathepsin B mRNA levels, and in addition demonstrated that all three of the melanoma variants secreted a latent form of cathepsin B into conditioned medium, which could be activated by limited proteolysis with pepsin. The levels of the latent enzyme released by the murine melanoma variants correlated well with the levels of cathepsin B mRNA and with the metastatic potentials as determined by spontaneous metastasis form a s.c. site.

Molecular cloning and sequencing of the cDNA for human membrane-bound carboxypeptidase M. Comparison with carboxypeptidases A, B, H, and N

Carboxypeptidase M, a widely distributed membrane-bound carboxypeptidase that can regulate peptide hormone activity, was purified to homogeneity from human placenta (Skidgel, R. A., Davis, R. M., and Tan, F. (1989) J. Biol. Chem. 264, 2236-2241). The NH2-terminal 31 amino acids were sequenced, and two complementary oligonucleotide probes were synthesized and used to isolate a carboxypeptidase M clone from a human placental cDNA library. Sequencing of the cDNA insert (2009 base pairs) revealed an open reading frame of 1317 base pairs coding for a protein of 439 residues. The NH2-terminal protein sequence matched the deduced amino acid sequence starting with residue 14. Hydropathic analysis revealed hydrophobic regions at the NH2 and COOH termini. The NH2-terminal 13 amino acids probably represent part of the signal peptide, and the COOH-terminal hydrophobic region may act either as a transmembrane anchor or as a signal for attachment to a phosphatidylinositol glycan moiety. The carboxypeptidase M sequence contains six potential Asn-linked glycosylation sites, consistent with its glycoprotein nature. The sequence of carboxypeptidase M was 41% identical with that of the active subunit of human plasma carboxypeptidase N, 41% identical with bovine carboxypeptidase H (carboxypeptidase E, enkephalin convertase), and 15% with either bovine pancreatic carboxypeptidase A or B. Many of the active site residues identified in carboxypeptidases A and B, including all of the zinc-binding residues (2 histidines and a glutamic acid), are conserved in carboxypeptidase M. These data indicate that all of the metallocarboxypeptidases are related, but the nondigestive carboxypeptidases with more specialized functions, present in cell membranes, blood plasma, or secretory granules (i.e., carboxypeptidase M, carboxypeptidase N and carboxypeptidase H), are more closely related to each other (41-49% identity) than they are to carboxypeptidase A or B (15-20% identity).

Conservation of the sequence of islet amyloid polypeptide in five mammals is consistent with its putative role as an islet hormone

Islet amyloid polypeptide (IAPP) is a 37-amino acid peptide found in the pancreatic amyloid deposits of type II (non-insulin-dependent) diabetic patients and insulinomas. We previously reported the nucleotide sequence of a human cDNA, which indicated that IAPP is a C-terminally amidated peptide derived by proteolytic processing of an 89-amino acid precursor. We now report the isolation of cDNA clones coding for cat, rat, mouse, and guinea pig IAPP precursors, obtained using the combination of "amplification of homologous DNA fragments" (AHF) and "rapid amplification of cDNA ends" (RACE). The predicted structure of IAPP precursors from these four mammals revealed that the IAPP moiety of each is derived from an 89- to 93-amino acid precursor by proteolytic processing and is likely to be amidated at the C terminus. The predicted amino acid sequence identities between the IAPP domains of these four mammals and human IAPP were 89% (cat), 84% (rat and mouse), and 78% (guinea pig). Within the IAPP domains, the N-terminal and C-terminal amino acid sequences are very highly conserved among the mammals, as is also the case with a structurally related neuropeptide, calcitonin-gene-related peptide (CGRP), suggesting that IAPP and CGRP interact with similar though not identical receptors. By contrast, the N- and C-terminal propeptides of the IAPP precursor show very little sequence conservation, which suggests that these regions do not represent additional biologically active molecules. Interspecies variations in the amino acid sequence of residues 20-29 of IAPP may account for the presence of amyloid deposits in the islets of humans and cats and their absence in rats and mice.

A mutant human proinsulin is secreted from islets of Langerhans in increased amounts via an unregulated pathway

A coding mutation in the human insulin gene (His-B10----Asp) is associated with familial hyperproinsulinemia. To model this syndrome, we have produced transgenic mice that express high levels of the mutant prohormone in their islets of Langerhans. Strain 24-6 mice, containing about 100 copies of the mutant gene, were normoglycemic but had marked increases of serum human proinsulin immunoreactive components. Biosynthetic studies on isolated islets revealed that approximately 65% of the proinsulin synthesized in these mice was the human mutant form. Unlike the normal endogenous mouse proinsulin, which was almost exclusively handled via a regulated secretory pathway, up to 15% of the human [Asp10]proinsulin was rapidly secreted after synthesis via an unregulated or constitutive pathway, and approximately 20% was degraded within the islet cells. The secreted human [Asp10]proinsulin was not processed proteolytically. However, the processing of the normal mouse and human mutant proinsulins within the islets from transgenic mice was not significantly impaired. These findings suggest that the hyperproinsulinemia of the patients is the result of the continuous secretion of unprocessed mutant prohormone from the islets via this alternative unregulated pathway.

Appalachian spring: variations on ancient gastro-entero-pancreatic themes in New World mammals

Studies of guinea pig genomic and/or cDNA clones encoding the gastro-entero-pancreatic (GEP) hormones--insulin, glucagon and pancreatic polypeptide--as well as portions of the insulin receptor, are described. Multiple clustered substitutions (localized rapid mutation acceptance) altering the biological properties of both insulin and glucagon have been revealed, but this does not appear to be the case with either pancreatic polypeptide or those regions of guinea pig insulin receptor cDNAs that have been examined thus far. These findings suggest that novel selective pressures operative in the New World environment, in which these animals evolved in isolation from Old World mammalian species, have led to altered solutions to problems related to the regulation of growth and carbohydrate metabolism.

Use of in vitro DNA amplification to screen family members for an insulin gene mutation

The DNA polymerase chain reaction can be a powerful tool for amplifying selected segments of genomic DNA for investigation of point mutations that are inaccessible via classic restriction-fragment-length polymorphism analysis. We have applied this method to an analysis of the incidence of heterozygosity for the mutant insulin allele insulin Wakayama (A3 Val----Leu) in two unrelated Japanese families having the hyperinsulinemic mutant insulin syndrome. The results indicate that this method is simple, sensitive, and accurate and should be useful for screening larger (diabetic) populations to detect single-base substitutions in the insulin gene that lead to either altered (pro)insulin structure and/or insulin production.

Expression of rat and mouse cathepsin B precursors in Escherichia coli

Vectors for the expression of mouse preprocathepsin B and rat procathepsin B, under the control of a modified lac operon regulatory region, in plasmid pKK233-2 were constructed. In rapidly growing cells induction of preprocathepsin B was cytotoxic. Immune precipitable cathepsin B, compatible in size with that expected for the unglycosylated proenzyme, was produced in both constructs. However, pepsin digestion of extracts did not produce any cathepsin B activity, indicating either that the recombinant forms are not correctly folded or were produced at such low levels that activity could not be detected.

A mutation in the B chain coding region is associated with impaired proinsulin conversion in a family with hyperproinsulinemia

Gruppuso et al. [Gruppuso, P.A., Gordon, P., Kahn, C. R., Cornblath, M., Zeller, W. P. & Schwartz, R. (1984) N. Engl. J. Med. 311, 629-634] have recently described a family in which hyperproinsulinemia is inherited in an autosomal dominant pattern, suggesting a structural abnormality in the proinsulin molecule as the basis for this disorder. However, unlike two previous kindreds with a similar syndrome, the serum proinsulin-like material in this family did not appear to be an intermediate conversion product but instead behaved like normal human proinsulin by several criteria. To further characterize this disorder we isolated and sequenced the insulin gene of the propositus. Leukocyte DNA was cloned into lambda-WES and recombinants containing the two insulin alleles, lambda MD41 and lambda MD51, were isolated by plaque hybridization. DNA sequencing of lambda MD51 showed that it contained the normal coding sequence for human preproinsulin. Sequence analysis of lambda MD41, however, revealed a single nucleotide substitution in the codon for residue 10 of proinsulin (CAC----GAC) that predicts the exchange of aspartic acid for histidine in the insulin B chain region. This mutation was also found in an insulin allele cloned from a second affected family member (propositus's father). These results, along with the linkage analysis of Elbein et al. [Elbein, S.C., Gruppuso, P., Schwartz, R., Skolnick, M. & Permutt, M.A. (1985) Diabetes 34, 821-824], strongly implicate this mutation as the cause of the hyperproinsulinemia in this family. Inhibition of the conversion of proinsulin to insulin may be related to altered folding and/or self-association properties of the [Asp10]proinsulin.

Insulin Wakayama: familial mutant insulin syndrome in Japan

We describe a family from Japan displaying the mutant insulin syndrome with hyperinsulinaemia and an increased insulin: C-peptide molar ratio. Serum insulin isolated from several family members showed reduced in vitro biological activity, and analysis by high performance liquid chromatography revealed a peak co-eluting with human insulin and a second species of increased hydrophobicity co-migrating with the previously reported Insulin Wakayama. The insulin genes from the propositus were cloned and sequenced, revealing one normal allele; the second allele, encoding a leucine for valine amino acid substitution at position 3 of the insulin A chain, was similar to that previously described for Insulin Wakayama. Synthesized [LeuA3] insulin showed 0.14% of receptor binding activity on rat adipocytes and a 10-fold prolonged half-life in a somatostatin-infused dog compared with human insulin. The finding of the same mutant gene in two unrelated Japanese families suggests that Insulin Wakayama may be discovered in additional Japanese families with hyperinsulinaemia and/or diabetes.

Staphylococcus aureus bacteremia: significance of hyperbilirubinemia

We studied 233 consecutive episodes of Staphylococcus aureus bacteremia in 230 patients between 1980 and 1984 at a community teaching hospital. Bacteremia was community-acquired in 78 episodes, acquired from nursing homes in 22 episodes and hospital-acquired in 133 episodes. The over-all mortality was 48.9%. Patients greater than or equal to 60 years had higher mortality (62.0%) than patients less than 60 years old (25.3%). Hospital-acquired bacteremia was associated with a higher mortality (59.4%) than community-acquired bacteremia (29.5%). The respiratory tract as the portal of entry of bacteremia was associated with a higher mortality (80.4%), as compared to 53.5% when the portal of entry was undetermined, and 28.1% when the portal of entry was other sources. Increasing serum creatinine levels were associated with increasing mortality: less than 88.4 mumol/l (26.5%), 97.2-168.0 mumol/l (51.1%), and greater than 176.8 mumol/l (67.9%). Increasing serum bilirubin levels were also associated with increasing mortality: less than 17.1 mumol/l (40.6%), 18.8-49.6 mumol/l (57.1%), and greater than 51.3 mumol/l (84.2%). Very high leukocyte counts were associated with higher mortality: greater than 20 X 10(9)/l (73.9%), 10-20 X 10(9)/l (37.4%), and less than 10 X 10(9)/l (45.8%).

T-cell receptor alpha-chain gene is split in a human T-cell leukemia cell line with a t(11;14)(p15;q11)

Chromosomal rearrangements in malignant T-cell disease frequently involve the chromosome bands containing the T-cell receptor genes. The RPMI 8402 cell line, which was established from the leukemia cells of a patient with T-cell acute lymphoblastic leukemia, is characterized by a translocation involving chromosome 14 (band q11) and chromosome 11 (band p15) [t(11;14)(p15;q11)]. By using in situ chromosomal hybridization and Southern blot analysis to examine RPMI 8402 cells, we determined that the break at 14q11 occurs within the variable region sequences of the T-cell receptor alpha-chain gene (TCRA); the break at 11p15 occurs between the HRAS1 gene and the genes for insulin and the insulin-like growth factor 2. These results suggest that the TCRA sequences activate a cellular gene located at 11p15 in malignant T-cell disorders.

Nucleotide and predicted amino acid sequences of cloned human and mouse preprocathepsin B cDNAs

Cathepsin B is a lysosomal thiol proteinase that may have additional extralysosomal functions. To further our investigations on the structure, mode of biosynthesis, and intracellular sorting of this enzyme, we have determined the complete coding sequences for human and mouse preprocathepsin B by using cDNA clones isolated from human hepatoma and kidney phage libraries. The nucleotide sequences predict that the primary structure of preprocathepsin B contains 339 amino acids organized as follows: a 17-residue NH2-terminal prepeptide sequence followed by a 62-residue propeptide region, 254 residues in mature (single chain) cathepsin B, and a 6-residue extension at the COOH terminus. A comparison of procathepsin B sequences from three species (human, mouse, and rat) reveals that the homology between the propeptides is relatively conserved with a minimum of 68% sequence identity. In particular, two conserved sequences in the propeptide that may be functionally significant include a potential glycosylation site and the presence of a single cysteine at position 59. Comparative analysis of the three sequences also suggests that processing of procathepsin B is a multistep process, during which enzymatically active intermediate forms may be generated. The availability of the cDNA clones will facilitate the identification of possible active or inactive intermediate processive forms as well as studies on the transcriptional regulation of the cathepsin B gene.

Mutations in the guinea pig preproglucagon gene are restricted to a specific portion of the prohormone sequence

A cDNA clone encoding guinea pig preproglucagon has been isolated from a pancreatic cDNA library. The predicted amino acid sequence of proglucagon is highly conserved in all regions, in comparison to other mammals, except for the C-terminal portion of the 29-residue glucagon region, in which 5 amino acid substitutions have occurred. These changes may serve to offset the reduced receptor-binding potency of the highly mutated insulin in this New World species.

Differences in cathepsin B mRNA levels in rat tissues suggest specialized functions

The tissue distribution of mRNAs encoding two lysosomal proteases, cathepsin B and cathepsin D, was examined using cloned cDNAs to probe Northern and dot blots of RNAs extracted from various rat tissues. Cathepsin B mRNA showed a wide range of variation in expression in the tissues analyzed with the highest concentrations found in spleen and kidney, while the cathepsin D mRNA levels were relatively uniform in these same tissues. Significant quantities of cathepsin B mRNA were detected in total RNA from isolated islets of Langerhans but was not detectable in equivalent amounts of RNA from whole pancreas. The wide variations in tissue levels of cathepsin B mRNA suggest that tissue specific controls may regulate its expression and are compatible with the participation of this protease in specialized cellular functions other than intralysosomal protein degradation.

Guinea pig preproinsulin gene: an evolutionary compromise?

We characterized a clone carrying the guinea pig preproinsulin gene, which, in contrast to other mammalian preproinsulin genes, is highly divergent in its regions encoding the B and A chains of mature insulin. Blot hybridization analysis indicates that this gene is present in only one copy in the guinea pig genome and that other normal or mutated preproinsulin genes do not exist in this animal. Moreover, the position of introns in this gene and the homology of its 3' flanking region to the corresponding regions of other sequenced mammalian genes show that it has been derived from the common mammalian stock. The rapid evolution of the region encoding the B and A chains can be interpreted, according to our sequence-divergence analysis, as due to the fixation of both neutral and adaptive mutations.

Familial hyperinsulinemia due to a structurally abnormal insulin. Definition of an emerging new clinical syndrome

We have identified a patient with mild diabetes, marked fasting hyperinsulinemia (89 to 130 microU of insulin per milliliter), and a reduced fasting C-peptide: insulin molar ratio of 1.11 to 1.50 (normal, greater than 4). The patient responded normally to exogenous insulin. However, her endogenous immunoreactive insulin showed reduced biologic activity during a glucose-clamp study with hyperglycemia and a reduced ability to bind to the insulin receptor and stimulate glucose transport in vitro. Family studies showed that five additional relatives in three generations had variable degrees of glucose intolerance, marked hyperinsulinemia, and a reduced peripheral C-peptide:insulin molar ratio. Restriction-endonuclease cleavage of DNA isolated from circulating leukocytes in the patient and in family members with hyperinsulinemia revealed loss of the MboII recognition site in one allele of the insulin gene--consistent with a point mutation at position 24 or 25 in the insulin B chain. Other studies using high-pressure liquid chromatography and detailed gene analysis have identified the defect as a serine for phenylalanine substitution at position 24 of the insulin B chain. The secretion of a structurally abnormal insulin should be considered in patients with hyperinsulinemia who respond normally to exogenous insulin and have a reduced C-peptide:insulin molar ratio. Glucose tolerance may range from relatively normal to overtly diabetic.

Studies on mutant human insulin genes: identification and sequence analysis of a gene encoding [SerB24]insulin

Both alleles of the insulin gene of a patient with mild diabetes [maturity-onset-diabetes-of-the-young (MODY)-type syndrome] associated with hyperinsulinemia have been cloned, and the sequences have been determined. One allele contained a mutation (single nucleotide transition) in the coding sequence for the B chain at position 24 (TTC leads to TCC), resulting in the loss of a restriction enzyme (Mbo II) cleavage site in the gene. This mutation results in the substitution of serine for phenylalanine in a critically important region of the insulin molecule that is intimately involved in receptor binding. Both insulin alleles were of the alpha type and, aside from a single nucleotide deletion in the 5' region of the normal allele, their sequences were identical to those previously determined.

Cloning and nucleotide sequence analysis of the dog insulin gene. Coded amino acid sequence of canine preproinsulin predicts an additional C-peptide fragment

A 4.0-kilobase HindIII/EcoRI-cleaved dog genomic DNA fragment was shown to contain the dog insulin gene by restriction mapping using a human insulin cDNA probe. This fragment was subsequently cloned in a lambda vector, and the nucleotide sequence of the dog insulin gene was determined. As in several other species, the insulin gene of the dog is interrupted by two intervening sequences, one of 151 base pairs located in the 5' untranslated region and the other of 264 base pairs occurring within the codon of the 7th amino acid of the C-peptide. Translation of the nucleotide sequence in one frame revealed the primary structure of canine preproinsulin. An interesting feature of the coded amino acid sequence is that it predicts a C-peptide of 31 amino acids, 8 residues longer than that reported by Peterson et al. (Peterson, J. D., Nehrlich, S., Oyer, P. E., and Steiner, D. F. (1973) J. Biol. Chem. 247, 4866-4871). The additional octapeptide sequence, Glu-Val-Glu-Asp-Leu-Gln-Val-Arg, is located NH2-terminal to the 23-residue C-peptide sequence described in the earlier report. Its coding sequence is interrupted by the second intervening sequence. The arginine at position 8 suggests that a trypsin-like cleavage may separate the NH2-terminal octapeptide from the remainder of the C-peptide during the post-translational processing of dog proinsulin in the pancreas. The revised C-peptide sequence suggests that the proinsulin C-peptide is more highly conserved in length and overall sequence than was previously supposed.

Biosynthesis and periplasmic segregation of human proinsulin in Escherichia coli

A plasmid containing human preproinsulin cDNA inserted into the endonuclease Pst I site of the ampicillinase gene of plasmid pBR322 was modified by excision of large portions of the ampicillinase-coding region to produce a variety of gene fusion combinations, many of which generated proteins detectable with antisera to insulin or human C peptide. In one case a perfect hybrid of the NH2-terminal half of the leader sequence of ampicillinase (residues -23 to -12) with the human preproinsulin prepeptide beginning at residue -13 was formed; the result was the synthesis and secretion of human proinsulin into the periplasmic space. We have characterized this protein immunologically and also by labeling it biosynthetically or by iodination followed by immunoprecipitation and automated amino acid sequence analysis. It contains the A and B chain regions of insulin as well as specific human C peptide immunodeterminants and is convertible to an insulin-like component by tryptic digestion. These results demonstrate that human proinsulin can be produced by bacteria and that this biosynthetic approach should prove feasible for the production of adequate amounts of human proinsulin for a variety of clinical studies and human insulin for therapeutic purposes.

Use of formylated yeast initiator Met tRNA to define the NH2-terminal residues of rat preproinsulin and pregrowth hormone

A method for unambiguously determining the initiator methionine residue and the adjacent NH2-terminal amino acid sequence of cell-free translation products of eukaryotic messenger RNA is described. In this procedure, the NH2 termini of nascent peptides are blocked by incorporating labeled formylmethionine instead of methionine, using yeast initiator tRNA in the wheat germ cell-free system. After immunoprecipitation of the desired product the radiolabeled material is treated with dansyl-Cl to irreversibly block all remaining free amino groups. The material is then deformylated by mild acid hydrolysis and subjected to automated Edman degradation. Only those products that had been synthesized with formylmethionine residues at their NH2-termini can then give rise to labeled phenylthiohydantoin derivatives during degradation. Using this method, we have defined the initiation sites in both rat preproinsulin and pregrowth hormone messenger RNAs.

Formation of biologically active peptides

Many small biologicaly active peptides are derived from larger precursor forms which fulfil a variety of roles in the synthesis, segregation and intracellular migration of secretory products. Limited proteolysis may occur at several stages during this process, giving rise to products that are either degraded (e.g. the prepeptides) or discharged coordinately from their cells of origin during exocytosis (e.g. insulin and C-peptide). Molecular defects have recently been found to occur at cleavage sites in proinsulin as well as in other proproteins, and these point mutations may, in some instances, be responsible for familial metabolic disorders. The nature and cell specificity of the proteolytic enzymes involved in the conversion of the various precursor forms remains unresolved. Recent studies in our laboratory have led to the identification of precursors of glucagon and somatostatin in rat islets of Langerhans. Analysis of tryptic maps of these precursors has shown that a trypsin-like enzyme would be sufficient to cleave the C-terminally located somatostatin sequence from its precursor (relative molecular mass 12,500), but that both trypsin-like and carboxypeptidase B-like enzymes would be necessary to cleave the internal glucagon sequence from its prohormone (relative molecular mass 18,000). Molecular cloning techniques have provided valuable new approaches to analysing the structures of a variety of precursor forms, including those for insulin, gastrin, growth hormone, adrenocorticotropic hormone and the endorphins, and in the future will undoubtedly shed more light on the structures of their chromosomal genes, the mechanisms regulating their expression, and their evolutionary origins.

Processing mechanisms in the biosynthesis of proteins

Limited proteolysis is a widely occurring mechanism in protein biosynthesis. Protein precursors can be classified according to their functions, localization within cell compartments, and enzymic cleavage mechanisms. The presecretory proteins represent an important class of very rapidly turning over precursors which play an early role in the sequestration of secretory products and whose cleavage appears to be intimately associated with structures formed at the ribosome-membrane junction during protein synthesis. A model is proposed which predicts that the prepeptide forms a beta-pleated sheet structure with other components of the membrane which results in the transfer of a loop of peptide across the microsomal membrane. Proinsulin is representative of the general class of proproteins that are processed post-translationally within their secretory cells either during the formation and maturation of secretory granules (peptides hormones and neurotransmitters, serum albumins) or during the assembly of macromolecular structures (virus capsules, membrane-associated enzyme complexes). The former group are cleaved by Golgi-associated proteases having tryptic and carboxypeptidase B-like specificity. Some precursors are secreted as such and processed extracellularly either in the circulation or at special sites (procollagens, zymogens, provenoms, vitellogenins).

Construction and selection of recombinant plasmids containing full-length complementary DNAs corresponding to rat insulins I and II

We have used a synthetic deoxydecanucleotide to generate an insulin-specific cDNA probe suitable for selecting transformants that contain nearly full-length cDNAs corresponding to the mRNAs coding for rat insulins I and II. Double-stranded cDNA was synthesized from x-ray-induced rat insulinoma poly(A)-RNA, inserted in pBR322 plasmid DNA by the homopolymeric tailing technique, and cloned in Escherichia coli chi 1776. Colony hybridization with oligonucleotide-primed cDNA yielded 16 positive clones of which 7 corresponded to rat insulin I mRNA and 9 to rat insulin II mRNA. Restriction endonuclease maps of representative clones of each group indicated that these contained the complete coding sequences, as was confirmed by nucleotide sequence analysis of the 5' region of the cloned DNA for rat insulin II. Nucleotide sequence analysis also established the amino acid sequence of the prepeptide of rat preproinsulin II. Comparison of the amino acid sequence of the prepeptides of rat preproinsulin I and II shows that three conservative amino acid substitutions have occurred in this region of the molecule.

Immunological and chemical characterization of bovine preproinsulin

Fetal bovine pancreatic poly(A)-containing RNA directs the synthesis of an insulin immunoreactive polypeptide that is larger than proinsulin, preproinsulin, in the wheat germ cell-free translation system. We have characterized this peptide in detail both immunologically and chemically and have shown that it is 2500 daltons larger than bovine proinsulin (8700 daltons), possesses both insulin and bovine C-peptide-specific antigenic determinants, and contains all the tryptic peptides found in bovine proinsulin. Preproinsulin synthesized in the wheat germ cell-free system was precipitated with approximately 4-fold greater efficiency by bovine proinsulin antiserum than by insulin antiserum. Additional evidence was obtained which indicated that the preprotein folds and undergoes correct sulfhydryl oxidation less efficiently than proinsulin, perhaps due to the presence of the hydrophobic NH2-terminal extension. Automated sequential Edman degradation of bovine preproinsulin revealed the presence of an additional NH2-terminal sequence of 23 residues, preceding the B chain segment of proinsulin. The positions of 6 of the 7 leucine residues found in the bovine preproinsulin extension were identical to those reported previously for the rat preproinsulins. This close sequence similarity between the extensions of the bovine and rat preproinsulins supports the hypothesis that these molecules fulfill similar biosynthetic functions in vivo.

Cell-free synthesis of rat preproinsulins: characterization and partial amino acid sequence determination

Whole nucleic acid fractions of isolated rat islets of Langerhans greatly stimulate incorporation of radioactive amino acids into protein in a wheat germ ribosomal system. Approximately 30% of the synthetic product is precipitated with antisera to insulin or proinsulin. Characterization of this material by gel chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicates a molecular mass of 11,500 daltons. Trypsin digestion releases intact A chain as well as tryptic fragments of the C-peptides and B chains of the two rat proinsulins. Automated sequence determination of labeled cell-free product purified by immunoprecipitation discloses the presence of 23 additional amino acids NH2-terminal to the B chain sequence of proinsulin. The partial amino acid sequence of this extension is as follows: NH2-X-Leu (Lys) Met-x-Phe-Leu-Phe-Leu-Leu (Lys) Leu-Leu-x-leu-X-X-X-X-X-X-X-X-proinsulin. On the basis of the above evidence we have designated this peptide preproinsulin.