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Direct-Acting Cholinergic Agonists: Pharmacological Actions00:59

Direct-Acting Cholinergic Agonists: Pharmacological Actions

Direct-acting cholinergic agonists exert their pharmacological actions by mimicking the effects of acetylcholine on postsynaptic muscarinic receptors to generate parasympathetic responses. These agents elicit a range of physiological responses, including cardiovascular effects. For example, activation of muscarinic receptors induces bradycardia, decreased cardiac output, reduced peripheral resistance, and consequent hypotension. In the eye, stimulation of M3 receptors leads to smooth muscle...
Cholinergic Antagonists: Pharmacokinetics01:24

Cholinergic Antagonists: Pharmacokinetics

Cholinergic antagonists—such as antimuscarinics—are available in oral, topical, ocular, parenteral, and inhalational formulations. Most antimuscarinics are oral formulations,  while scopolamine is available as a topical patch, and ipratropium and tiotropium are available as inhalation aerosols or powders. Atropine, tropicamide, and cyclopentolate are topically instilled in the eye. Most antimuscarinics are lipid-soluble and readily absorbed from the gastrointestinal tract and the conjunctiva.
Cholinergic Antagonists: Pharmacological Actions01:28

Cholinergic Antagonists: Pharmacological Actions

Antimuscarinic drugs block muscarinic receptors in multiple systems, including the gut, eye, smooth muscles, respiratory tract, cardiovascular, and central nervous systems. They produce similar effects with varying selectivity depending on the specific agent and tissue. Here are the key pharmacological actions of antimuscarinics:
Gastrointestinal Effects: Antimuscarinics reduce gut contractions, increase gastric emptying, and slow intestinal transit. They partly inhibit gastric acid secretion...
Cholinergic Antagonists: Therapeutic Uses01:26

Cholinergic Antagonists: Therapeutic Uses

Antimuscarinic drugs have various therapeutic applications by inhibiting parasympathetic stimulation in different systems. Here are the key therapeutic uses of antimuscarinics:    
Respiratory Tract: Ipratropium, aclidinium, and tiotropium treat asthma, chronic bronchitis, and chronic obstructive pulmonary disease (COPD). They protect against bronchoconstriction caused by irritants like cigarette smoke, sulfur dioxide, and ozone. They also help reduce nasopharyngeal secretions in common...
Drugs Affecting GI Tract Motility: Dopamine Receptor Antagonists01:28

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Prokinetic agents are specialized medications that stimulate gastrointestinal (GI) motility, promoting food movement through the GI tract. Dopamine, an inhibitory neurotransmitter, plays a significant role in this process, reducing GI motility and indirectly controlling the speed of digestion. Dopamine receptor antagonists, such as metoclopramide and domperidone, offer a unique advantage as prokinetic agents. By blocking the dopamine receptors, these drugs increase GI motility, improving food...
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Anthelmintic drugs differ significantly from antiparasitic therapies targeting protozoa, primarily due to differences in parasite biology. Whereas most protozoal treatments act on proliferating cells, anthelmintics are typically directed against mature, nonproliferative helminths. The therapeutic approach considers the helminth's reliance on neuromuscular coordination, glucose metabolism, and microtubular integrity for survival, reproduction, and localization within the host. Most anthelmintics...

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Video Imaging and Spatiotemporal Maps to Analyze Gastrointestinal Motility in Mice
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Published on: February 3, 2016

クロマチンの改変とその機能

Tony Kouzarides1

  • 1The Gurdon Institute and Department of Pathology, University of Cambridge, Tennis Court Road, Cambridge, CB21QN, UK. t.kouzarides@gurdon.cam.ac.uk

Cell
|February 27, 2007
PubMed
まとめ
この要約は機械生成です。

核個体におけるヒストンの改変は,DNAの包装とタンパク質の相互作用を調節する. これらのエピジェネティックマークは,基本的な生物学的プロセスに影響を及ぼし,遺伝的に受け継がれます.

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07:41

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Published on: February 3, 2016

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科学分野:

  • 分子生物学は分子生物学である.
  • エピジェネティクス エピジェネティクス
  • クロマチンの生物学

背景:

  • DNAの包装の基本単位である核細胞は,多くの表面改変を特徴としています.
  • 少なくとも8つのヒストン改変のクラスが知られているが,各クラスは複数のサイトを持つ.

研究 の 目的:

  • クロマチンの構造と機能におけるヒストン変異の機能的役割を解明する.
  • これらの改変が生物学的プロセスと表遺伝子遺伝にどのように影響するかを理解する.

主な方法:

  • ヒストンの改変部位の特徴.
  • クロマチンの接触と非ヒストンタンパク質の徴募の分析.
  • 高次クロマチンの構造変調の調査.

主要な成果:

  • ヒストンの改変は,クロマチンの接触を妨害または促進する.
  • 修正は,ヒストン以外のタンパク質のクロマチンへの採用を導く.
  • ヒストンの改変により,高次元の染色体構造と酵素複合体のオーケストレーションが決定される.

結論:

  • ヒストンの改変は,染色体組織とDNA操作の重要な調節因子である.
  • これらの変異は,基本的な生物学的プロセスにおいて重要な役割を果たします.
  • ヒストンの改変は,表遺伝子遺伝を媒介する可能性がある.