107090-96-0

Basic information

• Product Name: CCAP
• Synonyms: CRUSTACEAN CARDIOACTIVE PEPTIDE;CRUSTACEAN CARDIOACTIVE PEPTIDE, AMIDE;CCAP;CCAP, AMIDE;H-PRO-PHE-CYS-ASN-ALA-PHE-THR-GLY-CYS-NH2;PRO-PHE-CYS-ASN-ALA-PHE-THR-GLY-CYS;PRO-PHE-CYS-ASN-ALA-PHE-THR-GLY-CYS-NH2;Crustacean Cardioactive Peptide (CCAP), amide
• CAS NO: 107090-96-0
• Molecular Formula: C₄₂H₅₇N₁₁O₁₁S₂
• Molecular Weight: 956.1
• Mol File: 107090-96-0.mol

Chemical Properties

• Appearance: /
• Storage Temp.: -15°C
• CAS DataBase Reference: CCAP(CAS DataBase Reference)
• NIST Chemistry Reference: CCAP(107090-96-0)
• EPA Substance Registry System: CCAP(107090-96-0)

Safety Data

• Hazardous Substances Data: 107090-96-0(Hazardous Substances Data)

Usage

Uses

Used in Neuropeptide Research:
CCAP is used as a research tool for studying the functions and mechanisms of neuropeptides in arthropods. Its highly conserved nature makes it an ideal candidate for investigating the roles of neuropeptides in various physiological processes, such as cardioacceleration and ecdysis.
Used in Insect and Crustacean Physiology:
CCAP is used as a physiological factor in the study of insect and crustacean physiology, particularly in the context of cardioacceleration and ecdysis. Understanding the role of CCAP in these processes can provide insights into the regulation of these essential functions in arthropods.
Used in Pharmaceutical Development:
CCAP has potential applications in the development of pharmaceuticals targeting arthropod-specific physiological processes. By modulating the activity of CCAP or its receptors, it may be possible to develop drugs that can control insect populations or affect crustacean behavior for various purposes, such as pest control or aquaculture.
Used in Comparative Neurobiology:
CCAP is used as a comparative tool in neurobiology to study the evolution and conservation of neuropeptide systems across different species. By comparing the structure, function, and expression patterns of CCAP in various arthropods, researchers can gain insights into the evolutionary history and diversification of neuropeptide signaling pathways.

Structure

CCAP is a cyclic amidated nonapeptide, including two Cys residues that form a disulfide bond. Amidation is crucial for biological activity.

?Discovery

The crustacean cardioactive peptide (CCAP) was originally identified from the central nervous system (CNS) of the crab Carcinus maenas, based on its heart stimulatory activity.An identical neuropeptide and the gene encoding a single copy of CCAP were later identified or annotated in many other insects and crustaceans.

Biological functions

CCAP acts on the heart to elicit increased frequency and amplitude of the heartbeat in crustaceans and insects.Its main central role is to induce the specific ecdysis behavior in moths.In R. prolixus, CCAP proved to be essential for successful ecdysis and development.Also, physiological and genetic experiments indicate that CCAP acts together with myoinhibitory peptides and the bursicon subunit (pburs) to control ecdysis behavior.In feeding cockroaches, CCAP is released from midgut endocrine cells to stimulate α-amylase and protease activity in the intestine.

Related news

Functions of duplicated genes encoding CCAP (cas 107090-96-0) receptors in the red flour beetle, Tribolium castaneum08/17/2019

Crustacean cardioactive peptide (CCAP) is a nonapeptide originally isolated from the shore crab, Carcinus maenas, based on its cardioacceleratory activity. This peptide is highly conserved in insects and other arthropods. In insects CCAP also has an essential role in ecdysis behavior. We previou...detailed

Fine structure of Leptomyxa ambigua n. sp. CCAP (cas 107090-96-0) 1546/2 strain, formerly known as “Rhizamoeba flabellata” (Amoebozoa, Tubulinea, Leptomyxida)08/14/2019

The species Leptomyxa flabellata was described by Goodey in 1915 and re-isolated by Pussard and Pons in 1976. It seems that it was never seen (or never recognized) again since that time. The strain designated as “Leptomyxa flabellata CCAP 1546/2” was studied by Cann in 1984, however the qualit...detailed

The influence of photoperiod and light intensity on the growth and photosynthesis of Dunaliella salina (chlorophyta) CCAP (cas 107090-96-0) 19/3008/12/2019

The green microalga Dunaliella salina survives in a wide range of salinities via mechanisms involving glycerol synthesis and degradation and is exploited for large amounts of nutraceutical carotenoids produced under stressed conditions. In this study, D. salina CCAP 19/30 was cultured in varying...detailed

CCAP (cas 107090-96-0) 1 Year Later: Challenges and Accomplishments08/11/2019

University of Texas Medical Branch (UTMB) implemented the Clinical Competency and Advancement Program (CCAP) in January 2011. The program, built upon American Nurse Association (ANA) standards,1 is a professional development tool for competency assessment, performance evaluation, and career adva...detailed

Relevant articles and documents

Formation of peptide disulfide bonds through a trans-dibromido-Pt(IV) complex oxidation reaction: Kinetic and mechanistic analyses

A trans-dibromido-Pt(IV) complex [PtBr2(en)2]Br2 was synthesized and evaluated for the synthesis of peptide disulfide bonds in this work. The reactions between the Pt(IV) complex and dicysteine-containing peptides were carried out in various aqueous solutions. As a result, excellent yields with fast reaction rates were achieved. Methionine residue was intact when the Pt(IV) complex reacted with a dicysteine and methionine-containing peptide. 3,6-Dioxa-1,8-octanedithiol (DODT) was selected as a model compound of the dicysteine-containing peptide. Kinetic studies for the reaction between the Pt(IV) complex and DODT were performed in different pH solutions. It is first-order both in [Pt(IV)] and in [DODT]. A reaction mechanism was proposed accordingly. The kinetic and mechanistic results demonstrated that the reaction rate for the formation of peptide disulfide bond via the Pt(IV) oxidation is increased with the increase of pH of the reaction medium. The protolytic constants of the two thiol groups in peptide also play a critical role in reaction rate. On the other hand, kinetic studies demonstrated that the Pt(IV) complex trans-[PtBr2(en)2]2+ can be used in an acidic medium for the purpose of synthesis of disulfide bonds.

Construction of disulfide bonds in peptides via immobilized platinum(IV) complex oxidation

A novel TentaGel resin supported platinum(IV) complex named TentaGel-Pt(IV) was synthesized and characterized by SEM, XPS, ICP-MS and UV–vis spectrophotometry. The formation of intramolecular disulfides in eleven dithiol-containing peptides of variable lengths using TentaGel-Pt(IV) was investigated at room temperature. The disulfide-containing peptides were formed in excellent oxidation yields and were easily separated by filtration upon completion of the reaction. Excellent reusability of TentaGel-Pt(IV) was also achieved. The mechanism for construction of the disulfide bond in peptides via TentaGel-Pt(IV) oxidation was proposed.

A study to develop platinum(iv) complex chemistry for peptide disulfide bond formation

Platinum(iv) complexes with a heterocyclic ligand and an ancillary ligand have been investigated and applied for treating various tumour cell lines. Another application of the Pt(iv) complexes in forming peptide disulfide bonds was investigated in this work. For development of Pt(iv) complex chemistry for disulfide bond formation in peptides, two Pt(iv) complexes, [PtCl2(phen)(en)]Cl2 and [PtCl2(bpy)(en)]Cl2, were synthesized and characterized using elemental analysis, ESI-MS and NMR. Subsequently, they were investigated as oxidants for the formation of disulfide bonds in various peptides. Excellent purities and yields of disulfide-containing peptides were achieved when the reactions were carried out in aqueous solution. The reactions were completed rapidly in a wide range of pH values even in acidic medium at room temperature. An intramolecular disulfide bond was formed in each of the peptides in a solution containing two dithiol-containing peptides, making the Pt(iv) complexes useful for generating disulfide-containing peptide libraries. In addition, the two Pt(iv) complexes can be used as oxidants for the synthesis of disulfide bonds on a resin, which is a more convenient method to synthesize disulfide-containing peptides through automation.