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Regulation of Expression Occurs at Multiple Steps02:24

Regulation of Expression Occurs at Multiple Steps

Gene expression can be regulated at almost every step from gene to protein. Transcription is the step that is most commonly regulated. This involves the binding of proteins to short regulatory sequences on the DNA. This association can either promote or inhibit the transcription of a gene associated with the respective sequence.
Transcription results in the generation of precursor (pre-mRNA) that consists of both exons and introns, which needs further processing before being translated to a...
Regulation of Expression Occurs at Multiple Steps02:24

Regulation of Expression Occurs at Multiple Steps

Gene expression can be regulated at almost every step from gene to protein. Transcription is the step that is most commonly regulated. This involves the binding of proteins to short regulatory sequences on the DNA. This association can either promote or inhibit the transcription of a gene associated with the respective sequence.
Transcription results in the generation of precursor (pre-mRNA) that consists of both exons and introns, which needs further processing before being translated to a...
Regulation of Expression at Multiple Steps01:23

Regulation of Expression at Multiple Steps

The gene expression in cells is regulated at different stages: (i) transcription, (ii) RNA processing, (iii) RNA localization, and (iv) translation. Transcriptional regulation is mediated by regulatory proteins such as transcription factors, activators, or repressors—these control gene expression by initiating or inhibiting the transcription of genes. Once a precursor or pre-mRNA is produced, it undergoes post-transcriptional modification, including 5' capping, splicing, and the addition of a...
Transcriptional Regulation: Riboswitches01:23

Transcriptional Regulation: Riboswitches

Riboswitches are RNA elements that regulate gene expression by altering their secondary structures in response to specific effector molecules. These elements, located in the leader regions of certain mRNAs, act as transcriptional regulators by toggling between alternative conformations to control downstream gene expression. Riboswitch-mediated regulation is a precise mechanism for modulating biosynthetic pathways, as exemplified by the riboflavin biosynthesis pathway in Bacillus...
Translational Regulation01:29

Translational Regulation

Translational regulation in prokaryotes ensures efficient protein synthesis by controlling ribosome access to mRNA. This regulation is mediated by secondary RNA structures, including translational riboswitches, RNA thermometers, and small RNAs (sRNAs), which respond to intracellular and environmental signals to modulate gene expression.Translational RiboswitchesRiboswitches in the leader region of mRNAs can regulate translation by altering the accessibility of the Shine-Dalgarno (SD) sequence,...
Chromatin Structure Regulates pre-mRNA Processing02:41

Chromatin Structure Regulates pre-mRNA Processing

In eukaryotic cells, nascent mRNA transcripts need to undergo many post-transcriptional modifications to reach the cell cytoplasm and translate into functional proteins. For a long time, transcription and pre-mRNA processing were considered two independent events that occur sequentially in the cell. However, it has now been well established that transcription and pre-mRNA processing are two simultaneous processes that are precisely regulated inside the cell.
The chromatin structure, especially...

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Video Experimental Relacionado

Updated: May 24, 2026

Real-time Analysis of Transcription Factor Binding, Transcription, Translation, and Turnover to Display Global Events During Cellular Activation
12:54

Real-time Analysis of Transcription Factor Binding, Transcription, Translation, and Turnover to Display Global Events During Cellular Activation

Published on: March 7, 2018

Complejidad funcional y regulación a través de la dinámica del ARN.

Elizabeth A Dethoff1, Jeetender Chugh, Anthony M Mustoe

  • 1Department of Chemistry and Biophysics, The University of Michigan, 930 North University Avenue, Ann Arbor, Michigan 48109-1055, USA.

Nature
|February 17, 2012
PubMed
Resumen
Este resumen es generado por máquina.

Los cambios en la conformación del ARN impulsan la regulación genética y los procesos vitales. Su dinámica flexible pero robusta es clave para las funciones celulares y las vías biológicas complejas.

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Exploring Sequence Space to Identify Binding Sites for Regulatory RNA-Binding Proteins
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Exploring Sequence Space to Identify Binding Sites for Regulatory RNA-Binding Proteins

Published on: August 9, 2019

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Real-time Analysis of Transcription Factor Binding, Transcription, Translation, and Turnover to Display Global Events During Cellular Activation
12:54

Real-time Analysis of Transcription Factor Binding, Transcription, Translation, and Turnover to Display Global Events During Cellular Activation

Published on: March 7, 2018

Exploring Sequence Space to Identify Binding Sites for Regulatory RNA-Binding Proteins
11:34

Exploring Sequence Space to Identify Binding Sites for Regulatory RNA-Binding Proteins

Published on: August 9, 2019

Área de la Ciencia:

  • Biología Molecular Biología Molecular
  • Genética La genética.
  • La bioquímica es la bioquímica.

Sus antecedentes:

  • Los cambios conformacionales del ARN son fundamentales para la regulación genética.
  • El ARN exhibe flexibilidad pero mantiene una dinámica robusta a través de interacciones específicas de emparejamiento de bases y apilamiento.
  • Los procesos celulares utilizan el comportamiento dinámico del ARN en vías complejas y productivas.

Objetivo del estudio:

  • Para explorar el papel de la dinámica del ARN en los procesos celulares.
  • Comprender cómo la flexibilidad conformacional del ARN contribuye a la complejidad biológica.
  • Investigar la integración de la dinámica del ARN en los circuitos genéticos y las vías bioquímicas.

Principales métodos:

  • Análisis de los cambios conformacionales del ARN.
  • Investigación de las interacciones de emparejamiento y apilamiento de bases de ARN.
  • Estudio de la integración del ARN en las vías celulares.

Principales resultados:

  • La dinámica del ARN es crucial para la regulación genética y los procesos fundamentales de la vida.
  • La flexibilidad estructural del ARN está limitada por interacciones favorables, lo que lleva a una dinámica robusta.
  • Los mecanismos celulares aprovechan efectivamente la dinámica del ARN para las vías funcionales.

Conclusiones:

  • La dinámica del ARN juega un papel general y fundamental en los procesos celulares.
  • La versatilidad de la dinámica del ARN apoya su integración en diversos circuitos genéticos.
  • Comprender la dinámica del ARN es clave para descifrar la complejidad biológica.