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Cadherin Peptide, avian Sale

(Synonyms: H2N-Leu-Arg-Ala-His-Ala-Val-Asp-Val-Asn-Gly-amide ) 目录号 : GP10127

Role in cell adhesion

Cadherin Peptide, avian Chemical Structure

Cas No.:127650-08-2

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1mg
¥315.00
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5mg
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10mg
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25mg
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产品描述

Cadherin Peptide, avian, (C44H75N17O13), a peptide with the sequence Leu-Arg-Ala-His-Ala-Val-Asp-Val-Asn-Gly-NH2, MW= 1050.2. Cadherins (named for "calcium-dependent adhesion") are a class of type-1 transmembrane proteins. They play important roles in cell adhesion, ensuring that cells within tissues are bound together. They are dependent on calcium (Ca2+) ions to function. Cadherins are synthesized as polypeptides and undergo many post-translational modifications to become the proteins which mediate cell-cell adhesion and recognition. Cadherins behave as both receptors and ligands. During development, their behavior assists in properly positioning cells - they are responsible for the separation of the different tissue layers, and for cellular migration. In the very early stages of development, E-cadherin (epithelial cadherin) is most greatly expressed. During the next stage, the development of the neuronal plate, N-cadherin (neural cadherin) is expressed and there is a decrease in E-cadherin. Finally, during the development of the notochord and the condensation of somites, E- P- and N-cadherin expression increases. After development, cadherins play a role in maintaining cell and tissue structure, and in cellular movement.

References:
1. Harris, Tony J.C., and Ulrich Tepass. "Adherins Junctions: From Molecules to Morphogenesis" Nature Reviews Molecular Cell Biology. 502-514. July 2010
2. Tepass, Ulrich, et al. "Cadherins in Embryonic and Neural Morphogenisis" Nature Reviews Molecular Cell Biology. November 2000.
3. Tepass, Ulrich, et al. "Cadherins in Embryonic and Neural Morphogenisis" Nature Reviews Molecular Cell Biology. November 2000.

Chemical Properties

Cas No. 127650-08-2 SDF
别名 H2N-Leu-Arg-Ala-His-Ala-Val-Asp-Val-Asn-Gly-amide
化学名 Cadherin Peptide, avian
Canonical SMILES CC(C)CC(C(=O)NC(CCCN=C(N)N)C(=O)NC(C)C(=O)NC(CC1=CN=CN1)C(=O)NC(C)C(=O)NC(C(C)C)C(=O)NC(CC(=O)O)C(=O)NC(C(C)C)C(=O)NC(CC(=O)N)C(=O)NCC(=O)N)N
分子式 C44H75N17O13 分子量 1050.17
溶解度 ≥ 105mg/mL in DMSO 储存条件 Store at -20°C
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1 mM 0.9522 mL 4.7611 mL 9.5223 mL
5 mM 0.1904 mL 0.9522 mL 1.9045 mL
10 mM 0.0952 mL 0.4761 mL 0.9522 mL
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Research Update

Identification of mammalian and invertebrate analogues of the avian calcium-dependent cell adhesion protein N-cadherin with synthetic-peptide directed antibodies against a conserved cytoplasmic domain

N-cadherin, a 130kD transmembrane adhesive glycoprotein, is a mediator of specific cellular interactions during development. Analysis of N-cadherin at the protein level, to date, has been largely dependent upon monoclonal antibody NCD-2 which recognizes only avian N-cadherin. We produced a monospecific polyclonal antiserum, C-NCAD(838-856), to a synthetic peptide corresponding to a portion of the highly conserved c-terminal cytoplasmic domain of chick N-cadherin. Using polyacrylamide gel electrophoresis and immunoblotting to map tissue distribution we show that the antiserum detects chick N-cadherin with a similar tissue distribution as NCD-2. Unlike NCD-2, however, anti-C-NCAD(838-856) recognizes N-cadherin analogues in a wide variety of species, including mouse, human, fish and drosophila. The results of comparative immunoblot studies demonstrate similar tissue-specific patterns and apparent molecular weight variation in the chick, mouse and human. This indicates that N-cadherin structure and expression, and most likely function as well, have been highly conserved in evolution. The antiserum recognizes an epitope unique to N-cadherin which is conserved among N-cadherins from a variety of species but is absent from other members of the cadherin gene family, as no immunoreactivity was detected with tissues bearing these other cadherins. The antiserum is thus a useful tool for the phylogenetic and biochemical investigation of N-cadherin from a variety of tissue sources.

Novel peptide mimetic small molecules of the HAV motif in N-cadherin inhibit N-cadherin-mediated neurite outgrowth and cell adhesion

The cell adhesion molecule, N-cadherin, stabilizes cell-cell junctions and promotes cellular migration during tissue morphogenesis in development. N-cadherin is also implicated in mediating tumor progression and metastasis in cancer. Therefore, developing antagonists of N-cadherin adhesion may be of therapeutic value in cancer treatment. The amino acid sequence HAV in the extracellular domain of N-cadherin is required for N-cadherin-mediated adhesion and migration. A cyclic peptide, ADH-1, derived from the N-cadherin HAV site is an effective antagonist of N-cadherin-mediated processes and is now in clinical trials for cancer chemotherapy. Because it is a peptide, ADH-1 has certain limitations as a drug, namely its metabolic instability and lack of oral delivery. Adherex set out to identify small molecule antagonists of N-cadherin, which would be more amenable to therapeutic use. Using three-dimensional computational screening, Adherex identified a set of small molecules as potential antagonists with sufficient structural similarity to the HAV region of N-cadherin. We tested the ability of these small molecules to interfere with two N-cadherin-dependent processes: neurite outgrowth (axonal migration) and N-cadherin-dependent cell adhesion. We identified 21 N-cadherin antagonists of varying potency. More importantly, our studies demonstrate that these compounds are significantly more potent than ADH-1 at perturbing N-cadherin-mediated processes. The IC(50) of ADH-1 is 2.33 mM while the IC(50) of the small molecules ranges from 4.5 to 30 microM. Given the efficacy of ADH-1 for treating cancer, these small molecule antagonists will be highly effective in treatment of cancer metastasis and conditions of aberrant neurite outgrowth, such as neuropathic pain.

Cell biological mechanisms regulating chick neurogenesis

Signalling pathways that regulate neural progenitor proliferation and neuronal differentiation have been identified. However, we know much less about how transduction of such signals is regulated within neuroepithelial cells to direct cell fate choice during mitosis and subsequent neuronal differentiation. Here we review recent advances in the experimentally amenable chick embryo, which reveal that this involves association of signalling pathway components with cell biological entities, including mitotic centrosomes and ciliary structures. This includes changing centrosomal localization of protein kinase A, which regulates Sonic hedgehog signalling and so neural progenitor status, and Mindbomb1, a mediator of Notch ligand activation, which promotes Notch signalling in neighbouring cells, and so is active in presumptive neurons. We further review cell biological events that underlie the later step of neuronal delamination, during which a newborn neuron detaches from its neighbouring cells and undergoes a process known as apical abscission. This involves inter-dependent actin and microtubule dynamics and includes dissociation of the centrosome from the ciliary membrane, which potentially alters the signalling repertoire of this now post-mitotic cell. Open questions and future directions are discussed along with technological advances which improve accuracy of gene manipulation, monitoring of protein dynamics and quantification of cell biological processes in living tissues.

Gastrulation EMT Is Independent of P-Cadherin Downregulation

Epithelial-mesenchymal transition (EMT) is an evolutionarily conserved process during which cells lose epithelial characteristics and gain a migratory phenotype. Although downregulation of epithelial cadherins by Snail and other transcriptional repressors is generally considered a prerequisite for EMT, recent studies have challenged this view. Here we investigate the relationship between E-cadherin and P-cadherin expression and localization, Snail function and EMT during gastrulation in chicken embryos. Expression analyses show that while E-cadherin transcripts are detected in the epiblast but not in the primitive streak or mesoderm, P-cadherin mRNA and protein are present in the epiblast, primitive and mesoderm. Antibodies that specifically recognize E-cadherin are not presently available. During EMT, P-cadherin relocalizes from the lateral surfaces of epithelial epiblast cells to a circumferential distribution in emerging mesodermal cells. Cells electroporated with an E-cadherin expression construct undergo EMT and migrate into the mesoderm. An examination of Snail function showed that reduction of Slug (SNAI2) protein levels using a morpholino fails to inhibit EMT, and expression of human or chicken Snail in epiblast cells fails to induce EMT. In contrast, cells expressing the Rho inhibitor peptide C3 rapidly exit the epiblast without activating Slug or the mesoderm marker N-cadherin. Together, these experiments show that epiblast cells undergo EMT while retaining P-cadherin, and raise questions about the mechanisms of EMT regulation during avian gastrulation.

Evolution and diversity in avian vocal system: an Evo-Devo model from the morphological and behavioral perspectives

Birds use various vocalizations to mark their territory and attract mates. Three groups of birds (songbirds, parrots, and hummingbirds) learn their vocalizations through imitation. In the brain of such vocal learners, there is a neural network called the song system specialized for vocal learning and production. In contrast, birds such as chickens and pigeons do not have such a neural network and can only produce innate sounds. Since each avian species shows distinct, genetically inherited vocal learning abilities that are related to its morphology, the avian vocal system is a good model for studying the evolution of functional neural circuits. Nevertheless, studies on avian vocalization from an evolutionary developmental-biological (Evo-Devo) perspective are scant. In the present review, we summarize the results of songbird studies and our recent work that used the Evo-Devo approach to understand the evolution of the avian vocal system.