Rodent submandibular gland peptide hormones and other biologically active peptides

The cervical sympathetic trunk-submandibular gland neuroendocrine axis plays an integral role in physiological adaptations and contributes to the maintenance of systemic homeostasis, particularly under the 'stress conditions' seen with tissue damage, inflammation, and aggressive behavior. The variety of polypeptides, whose release from acinar and ductal cells is under sympathetic nervous system control, offers coordinated and progressive levels of endocrine communication. Proteolytic enzymes (e.g. the kallikreins and furin maturases) are involved in the conversion of inactive precursors (e. g. Pro-EGF and SMR1) into biologically active molecules (e.g. EGF, SMR1-pentapeptide), which act on local or distant targets and thereby modulate the homeostatic process.     

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.     

Synthesis of biologically active cyclic peptides

1. The extent of racemization and the coupling yield in peptide synthesis were studied under high dilution conditions. The azide method yielded the best results. 2. Five linear penta-peptide precursors related to gramicidin S were subjected to cyclization in order to study how the difference in the sequence influences the yield and the ratio of cyclic dimer to monomer. The azide with the sequence of -L -Pro-L -Val-L -Orn(Z)-L -Leu-D -Phe- afforded diZ-gramicidin S in a high yield of 63%. 3. Alternaria mali toxin III, a cyclotetradepsipeptide phytotoxin, was synthesized. The activated linear tetradepsipeptide containing a D -Dap(Z) (N³-Z-D -2,3-diaminopropionic acid) residue at the N-terminus afforded the cyclic precursor (53%). The Dap residue in the precursor was converted into a ΔAla residue by Hofmann degradation to give the desired product.     

Lipotropin: precursor to two biologically active peptides.

Lipotropin appears to be the common precursor to β-MSH, a peptide with lipolytic activity, and C-Fragment, a peptide with potent opiate activity. The product formed is determined by the specificity of the activating enzymes.The amino acid sequence of β-MSH, the 18 residue melanocyte stimulating hormone, is contained within the central region of lipotropin (LPH), a 91 residue polypeptide. On this basis Li and his colleagues¹ suggested that LPH might be the prohormone of β-MSH. Bertagna, Lis and Gilardeau², on the other hand, were unable to demonstrate conversion of LPH to β-MSH $\text{in vitro}$ using pulse labelling techniques. If LPH is the precursor of β-MSH, formation of the hormone should be accompanied by release of the contiguous fragments of the prohormone and the fragments remain in the secretory particle of the gland. To obtain evidence on the biosynthetic origin of β-MSH, we have isolated peptides from pituitary in a search for the N- and C-fragments of the prohormone.     

Conformational and topographical considerations in the design of biologically active peptides

An outline of the basic considerations that are under development for the rational design of biologically active peptides and peptidomimetics is given. The necessary interplay of biophysical, chemical, and biological considerations is emphasized. The importance of properly designed biological assays to provide chemical information analogous to that from biophysical studies is discussed. The development of asymmetric synthesis in conjunction with conformational considerations for the preparation of specialized amino acids and amino acid mimetics is a critical aspect of the approach. The overall approach is illustrated with three examples from our laboratory: (1) the redesign of somatostatin to a highly potent and selective μ-opioid receptor antagonist using conformational and topographical considerations in design and for obtaining insights into the pharmacophor; (2) the use of topographical considerations for obtaining oxytocin antagonists; and (3) the application of designer amino acids prepared by asymmetric synthesis to obtain insight into the topographical requirements at δ-opioid receptors. © 1993 John Wiley & Sons, Inc.     

The discovery of catalytically active peptides through combinatorial chemistry

In recent years, ogliopeptides have enjoyed ever increasing interest in two areas: first, approaches to biomimetic enzyme-like activity; and second, as metal-free catalysts for enantioselective transformations of synthetic interest. The discovery and optimization of peptides for these purposes has often used the methodology of combinatorial chemistry. Examples include the screening of peptide libraries for ester and phosphate cleavage, aided by novel chromogenic and gel-based assays, and optimization of metal-free peptide catalysts for asymmetric epoxidation, enantioselective acylation/phosphorylation, conjugate addition to enimides, and hydrocyanation of imines (Strecker-reaction).     

Peptide-lipid interaction monitored by spin labeled biologically active melanocortin peptides

The present work comparatively analyzes the interaction of alpha-MSH and its more potent and long-acting analog [Nle4, D-Phe7]alpha-MSH (NDP-MSH) with lipid bilayers. The peptides were spin labeled with Toac (2,2,6,6-tetramethylpiperidine-1-oxyl-4-amino-4-carboxylic acid) at the N-terminal, as those derivatives had been previously shown to keep their full biological activity. Due to the special rigidity of the Toac covalent binding to the peptide molecule, this spin label is highly sensitive to the peptide backbone conformation and dynamics. The peptides were investigated both by the electron spin resonance (ESR) of Toac0 and the time resolved fluorescence of Trp9 present in the peptides. The Toac0 ESR of the membrane-bound peptides indicates that the two peptides are inserted into the bilayer, close to the bilayer surface, in rather similar environments. A residue titration around pKa 7.5, possibly that of His6, can be clearly monitored by peptide-lipid partition. Trp9 time resolved fluorescence indicates that the peptides, and their Toac-labeled derivatives, present rather similar conformations when membrane bound, though Trp9 in NDP-MSH, and in its Toac-labeled derivative, goes somewhat further down into the bilayer. Yet, Toac0 ESR signal shows that the Toac-labeled N-terminal of NDP-MSH is in a shallower position in the bilayer, as compared to the hormone.     

Release of biologically active peptides from Escherichia coli at subzero temperatures

Moss, C. Wayne (North Carolina State University, Raleigh), and M. L. Speck. Release of biologically active peptides from Escherichia coli at subzero temperatures. J. Bacteriol. 91:1105-1111. 1966.-Freezing and storage of Escherichia coli at -20 C in phosphate buffer resulted in loss of cell viability and a pronounced leakage of cellular material which had maximal absorption at 260 mmu. Greater loss in cell viability occurred when cells were frozen in distilled water, but only small amounts of 260 mmu absorbing material were detected. Unfrozen cells stored at 2 and 22 C in each menstruum showed little loss in viability, but cells in phosphate buffer released significant amounts of material during storage. Leakage material from cells in phosphate buffer contained greater amounts of ribonucleic acid and amino acids than did material from cells in distilled water. Leakage material from frozen cells contained protein in the form of peptides of relatively small molecular weight; this was not observed for unfrozen cells. These compounds protected a dilute cell suspension from the lethal effects of freezing, and also possessed biological activity for the recovery of cells which had been "injured" by freezing. Direct cell counts indicated that the material released was not a result of cell lysis.     

Microalgae as sources of pharmaceuticals and other biologically active compounds

In the last decade the screening of microalgae, especially the cyanobacteria (blue-green algae), for antibiotics and pharmacologically active compounds has received ever increasing interest. A large number of antibiotic compounds, many with novel structures, have been isolated and characterised. Similarly many cyanobacteria have been shown to produce antiviral and antineoplastic compounds. A range of pharmacological activities have also been observed with extracts of microalgae, however the active principles are as yet unknown in most cases. Several of the bioactive compounds may find application in human or veterinary medicine or in agriculture. Others should find application as research tools or as structural models for the development of new drugs. The microalgae are particularly attractive as natural sources of bioactive molecules since these algae have the potential to produce these compounds in culture which enables the production of structurally complex molecules which are difficult or impossible to produce by chemical synthesis.     

Ribosome-independent biosynthesis of biologically active peptides: Application of synthetic biology to generate structural diversity

Peptide natural products continue to play an important role in modern medicine as last-resort treatments of many life-threatening diseases, as they display many interesting biological activities ranging from antibiotic to antineoplastic. A large fraction of these microbial natural products is assembled by ribosome-independent mechanisms. Progress in sequencing technology and the mechanistic understanding of secondary metabolite pathways has led to the discovery of many formerly cryptic natural products and a molecular understanding of their assembly. Those advances enable us to apply protein and metabolic engineering approaches towards the manipulation of biosynthetic pathways. In this review we discuss the application potential of both templated and non-templated pathways as well as chemoenzymatic strategies for the structural diversification and tailoring of peptide natural products.     

The effects of intracerebroventricular administration of biologically active peptides in conscious sheep

The present study records the physiological effects of 24-hour intracerebroventricular infusion of a variety of biologically active peptides in conscious sheep. A number of peptides including AVP and TRH produced increases in mean arterial pressure, heart rate and body temperature. There was an overall positive correlation between peptide-induced changes in body temperature and changes in either mean arterial pressure or heart rate. TRH and β-endorphin had marked effects on behaviour and several peptides reduced food and water intake. Several peptides increased urinary sodium excretion, however, few peptides changed plasma electrolyte concentrations. TRH produced small effects on plasma ACTH and plasma glucose concentrations. The peptides in this study produced physiological changes which were probably mediated by their actions on the central nervous system.     

High-performance immobilized metal ion affinity chromatography of peptides: analytical separation of biologically active synthetic peptides

The separation of more than 30 biologically active synthetic peptides and their analogs on a high-performance immobilized metal ion affinity chromatography column is described. The metal chelating gel (TSK gel chelate-5PW) contains iminodiacetic acid (IDA) covalently coupled to a hydrophilic, resin-based matrix with a bead diameter of 10 micron. The retention of the peptides on Cu(II), Ni(II), and Zn(II) ions immobilized on the chelating gel showed that some of them can be separated by isocratic elution while the majority of them are retained and are separated into distinct fractions by elution with a linear imidazole gradient or with a continuously decreasing pH gradient. Of the three immobilized metal ions investigated here, the IDA-Cu(II) chelate column gave the best resolution irrespective of the type of gradient used. This is amply illustrated by the resolution of angiotensins I and II and their seven synthetic analogs. The results obtained here serve as guidelines for the future exploitation of this separation method for the efficient fractionation of a wide variety of peptides on an analytical or preparative scale.     

Synthesis and application of methyleneoxy pseudodipeptide building blocks in biologically active peptides

Summary. Pseudodipeptides H-Phe[CH₂O]Phe-OH, H-Tyr[CH₂O] Asp-OH and H-Pro[CH₂O]-D-Thr-OH were synthesized using the intramolecular Williamson reaction via substituted morpholin-3-one ring with the nitrogen atom protected with bulky Boc group. This protection and the substituent at C₅ position induced the stereospecific alkylation at the C₂ position introducing the side chain of the C-terminal amino acid mimetic. In the first pseudodipeptide a quenching of the enolate with benzaldehyde was followed by dehydration and corresponding double bond was hydrogenated with high stereospecific purity. In the other pseudodipeptides, this alkylation was carried out directly by tert-butyl 2-bromoacetate or acetaldehyde. However, in the latter reaction an R configuration of C₃ substituent in conjugated lactame ring was determined using a NOE NMR. Consequently, after opening this ring by acidic hydrolysis, the C-terminal part of corresponding pseudodipeptide possessed the side-chain of D-Thr mimetic, contrary to former one. Synthesized pseudodipeptides were introduced into HIV protease inhibitors and into peptides with oostatic activity.     

Conformational restrictions of biologically active peptides via amino acid side chain groups

Determining the relationships between conformation and biological activity in peptide hormones and neurotransmitters is an important goal of contemporary biology. A major difficulty in these studies is the conformational flexibility of most peptides and the high dependence of the conformations on environment. The question arises whether conformations determined in solution are relevant to those important to the peptide at the membrane receptor(s). One recent approach to overcome these difficulties has been the use of conformational constraints by covalent bonding of side chain groups of residues in the peptide. In this manner linear peptides are rendered cyclic, and cyclic peptides are further conformationally constrained either by ring contractions or by other conformational constraints. Biologically active peptides specifically designed by this approach have been found to possess several useful properties including: 1) greater conformational integrity; 2) increased agonist or antagonist potency; 3) prolonged biological activity; 4) increased enzymatic stability; and 5) increased specificity for a particular receptor. Careful applications of this approach have provided important new designs features for peptide structure-function studies, and new insights into peptide conformation-activity relationships for oxytocin, somatostatin, enkephalin, bradykinin, vasopressin, and other biologically active peptides.     

Role of proteolysis in posttranslational modifications of biologically active peptides and polypeptides]

Data from literature about the precursors of biologically active peptides and polypeptides in cells are summarized. Their processing by limited proteolysis and the enzymes which take part in this process are presented.