Cis-regulatory elements (CREs) or Cis''-regulatory modules (CRMs) are regions of non-coding DNA which regulate the transcription of neighboring genes. CREs are vital components of genetic regulatory networks, which in turn control morphogenesis, the development of anatomy, and other aspects of embryonic development, studied in evolutionary developmental biology.
CREs are found in the vicinity of the genes that they regulate. CREs typically regulate gene transcription by binding to transcription factors. A single transcription factor may bind to many CREs, and hence control the expression of many genes (pleiotropy). The Latin prefix cis means "on this side", i.e. on the same molecule of DNA as the gene(s) to be transcribed.
CRMs are stretches of DNA, usually 100–1000 DNA base pairs in length, where a number of transcription factors can bind and regulate expression of nearby genes and regulate their transcription rates. They are labeled as cis because they are typically located on the same DNA strand as the genes they control as opposed to trans, which refers to effects on genes not located on the same strand or farther away, such as transcription factors. One cis-regulatory element can regulate several genes, and conversely, one gene can have several cis-regulatory modules. Cis-regulatory modules carry out their function by integrating the active transcription factors and the associated co-factors at a specific time and place in the cell where this information is read and an output is given.
CREs are often but not always upstream of the transcription site. CREs contrast with trans-regulatory elements (TREs). TREs code for transcription factors.
The genome of an organism contains anywhere from a few hundred to thousands of different genes, all encoding a singular product or more. For numerous reasons, including organizational maintenance, energy conservation, and generating phenotypic variance, it is important that genes are only expressed when they are needed. The most efficient way for an organism to regulate gene expression is at the transcriptional level.
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This advanced Bachelor/Master level course will cover fundamentals and approaches at the interface of biology, chemistry, engineering and computer science for diverse fields of synthetic biology. This
Le but du cours est de fournir un aperçu général de la biologie des cellules et des organismes. Nous en discuterons dans le contexte de la vie des cellules et des organismes, en mettant l'accent sur l
La pléiotropie, du grec pleion (πλείων, « plus »), et tropê (τροπή, « changement ») qualifie un gène ou une protéine qui détermine plusieurs caractères phénotypiques. Par conséquent, le phénotype induit par une mutation de ce gène n'est pas le reflet de l'effet sur une seule et unique fonction induite par ce gène, mais la combinaison des effets sur plusieurs de ces caractères. Cela peut être un problème si on cherche à obtenir une variété pour sélectionner un phénotype particulier.
Un inactivateur (en anglais silencer) est une région d'ADN (séquence régulatrice) qui peut fixer des protéines pour diminuer la transcription de gène. Un gène peut posséder plusieurs amplificateurs. Ils sont généralement situés à assez loin du gène (jusqu'à nucléotides). Ou encore le gène et l'amplificateur ne sont pas forcément proches l'un de l'autre et peuvent même être sur deux chromosomes différents mais par contre le repliement de l'ADN dans le noyau leur permet une proximité physique.
A regulator gene, regulator, or regulatory gene is a gene involved in controlling the expression of one or more other genes. Regulatory sequences, which encode regulatory genes, are often at the five prime end (5') to the start site of transcription of the gene they regulate. In addition, these sequences can also be found at the three prime end (3') to the transcription start site. In both cases, whether the regulatory sequence occurs before (5') or after (3') the gene it regulates, the sequence is often many kilobases away from the transcription start site.
This course will provide the fundamental knowledge in neuroscience required to
understand how the brain is organised and how function at multiple scales is
integrated to give rise to cognition and beh
This course will provide the fundamental knowledge in neuroscience required to
understand how the brain is organised and how function at multiple scales is
integrated to give rise to cognition and beh
This course will provide the fundamental knowledge in neuroscience required to
understand how the brain is organised and how function at multiple scales is
integrated to give rise to cognition and beh
Explore la conception et les applications des commutateurs d'ARN, en mettant l'accent sur l'exploitation des principes de conception de la nature pour construire de nouveaux composants et réseaux biomoléculaires.
Se penche sur les réseaux de régulation des gènes, les techniques ChIP-seq, l'interprétation des données du projet ENCODE et la modélisation de l'expression génique différentielle.
Cis-genetic effects are key determinants of transcriptional divergence in discrete tissues and cell types. However, how cis- and trans-effects act across continuous trajectories of cellular differentiation in vivo is poorly understood. Here, we quantify al ...
Berlin2024
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Growing evidence indicates that transposable elements (TEs) play important roles in evolution by providing genomes with coding and non-coding sequences. Identification of TE-derived functional elements, however, has relied on TE annotations in individual s ...
2024
The adaptation of organisms to their environment depends on the innovative potential inherent to genetic variation. In complex organisms such as mammals, processes like development and immunity require tight gene regulation. Complex forms emerge more often ...