Monique said:DNA polymerase needs to bind to the start of a gene, for it to be able to transcribe and thus express a gene. Transcription factors are proteins expressed in a cell that have the ability to bind to certain DNA sequences. These DNA sequences lie upstream of a gene in the promotor region. After binding the transcription factors recruit many more proteins and thereby create a complex, this complex can modulate the structure of DNA so that the RNA polymerase transcription complex can bind and start transcribing the gene.
I hope that answers your question, after transcribing the gene you've got messenger RNA (mRNA), which still needs to be processed in several steps in order to get to proteins.
You are absolutely right.dpsguy said:Thanks Monique!
BTW, shouldn't that be RNA polymerase in the first line?
Yes, but you wouldn't call them transcription factors, but regulatory proteins. A very well-known and much-used example for gene-regulation is the LacZ gene (part of the lac operon). It is often cloned into a vector and used as a reporter gene.Just a little problem: if transcription factors(TFs) are protiens, then there must be a regulatory mechanism for them too. Does that mean that there are TFs that regulate TFs?
If so, does a feedback mechanism operate, like in operons? And how does the external environment of the cell come into the picture?
The link very helpfully given by Iansmith talks about external stimuli affecting cellular receptors which "can activate many downstream effector proteins". Then does this process bypass nuclear transcription? If not, what role do TFs have to play in this process?
Monique said:Yes, but you wouldn't call them transcription factors, but regulatory proteins. A very well-known and much-used example for gene-regulation is the LacZ gene (part of the lac operon). It is often cloned into a vector and used as a reporter gene.
The way it works is that the lac repressor protein (lacI) binds to the lac operon and thereby prevents transcription. When IPTG is added, the lac operon is de-repressed, due to the binding of IPTG to lacI, preventing it from binding the lac operon. Now the gene can be transcribed and translated into beta-galactosidase, a protein with enzymatic activity. The substrate for the enzyme is X-gal, which when cleaved leaves a water-insoluble blue product, which can be used as a reporter.
A way to envision the use of this LacZ protein is for instance to monitor whether you have cloned (inserted) a gene into a vector (a circular piece of DNA from viral origin). When the system is intact, you will get blue bacterial colonies (these are the 'test tubes' in which you perform the reaction), when the LacZ gene is disrupted by an inserted protein, you get white bacterial colonies.
There are many different pathways known that play a central role in signal transduction from the outside to the inside of the cell. Everything is highly regulated and there are often feedback mechanisms.
A well-known signal transduction pathway is the MAPK pathway, which is a kinase cascade where kinases phosphorylate kinases, which in turn will phosphorylate kinases. In this way the signal is greatly enhanced.
http://www.biocarta.com/pathfiles/h_mapkPathway.asp
The pathway in outline works like this: the epidermal growth factor receptor (EGFR) binds and is activated by the extracellular epidermal growth factor (EGF), by forming a dimer. The receptor-dimer can then cross-phosphorylate the tyrosines on its cytoplasmic tail.
Docking proteins such as GRB2, which contain an SH2 domain, can then bind to the phosphotyrosines. Then a guanine nucleotide exchange factor (GEF) binds to the SH3 domain of GRB2 and becomes active.
The GEF exchanges the GDP for a GTP on Ras, thereby activating it, which can continue to activate the protein kinase Raf. This sets off a whole set of kinases, which in the end go into the nucleus and signal to transcription factors (on the bottom in the diagram: Elk-1 c-FOS c-JUN ATF-2 SP-1 STAT-1 etc).
As seen in the LacZ example, some proteins will promote transcription, others will repress it. There is a whole other mechanism for gene repression/activation, which is based on histone-tail modifications. This is a very complex subject by itself.
dpsguy said:Does this mean that regulatory genes like the lacI gene are always being transcribed, irrespective of whether the LacZ gene is active or not?
dpsguy said:But this will not always work. Even if the gene is inserted properly but the protien does not interfere with the lacI protien,you will still get blue colonies. Or am I wrong in my understanding?
dpsguy said:Are the TFs being finally signalled here already present in the nucleus? If so, when were they transcribed? Or are the genes which code for these TFs activated at the end of the cascade? In that case, how are they repressd again?
dpsguy said:The functioning of operons seems to be much simpler than, say, the MAPK pathway.
dpsguy said:Are operons found only in lower organisms like prokaryotes, or also in humans?
dpsguy said:Conversely, are transcription factors and mechanisms like the MAPK pathway found in lower organisms too?
Monique said:RNA polymerase needs to bind to the start of a gene, for it to be able to transcribe and thus express a gene. Transcription factors are proteins expressed in a cell that have the ability to bind to certain DNA sequences. These DNA sequences lie upstream of a gene in the promotor region. After binding the transcription factors recruit many more proteins and thereby create a complex, this complex can modulate the structure of DNA so that the RNA polymerase transcription complex can bind and start transcribing the gene.
E.coli sigma factors:
σ70 (RpoD) - the "housekeeping" sigma factor, transcribes most genes in growing cells.
σ38 (RpoS) - the starvation/stationary phase sigma factor
σ28 (RpoF) - the flagellar sigma factor
σ32 (RpoH) - the heat shock sigma Factor
σ24 (RpoE) - the extracytoplasmic stress sigma factor
σ54 (RpoN) - the nitrogen-limitation sigma factor
σ19 (FecI) - the ferric citrate sigma factor
Monique said:Transcription factors bind to specific DNA sequences, so they activate specifically the genes that have the DNA sequence in its promoter. A single transcription factor usually regulates several genes in the same pathway, this is ofcourse efficient.
Genes can be thought of as instructions for building proteins, which are essential for various functions in our bodies. When a gene is switched on, its instructions are read and the corresponding protein is made. When a gene is switched off, its instructions are not read and no protein is made.
Genes switch on and off through a process called gene regulation. This involves a complex network of molecular signals and interactions that control when and where a gene is expressed. Different factors such as environmental cues, hormones, and other genes can influence this process.
Yes, genes can be switched on and off permanently through a process called epigenetics. This involves chemical modifications to the DNA or the proteins associated with it, which can either enhance or repress gene expression. These modifications can be influenced by environmental factors and can be passed down from one generation to the next.
The consequences of genes switching on and off can vary greatly depending on the specific gene and its role in the body. In some cases, it can lead to the production of essential proteins that are needed for normal bodily functions. In other cases, it can contribute to the development of diseases or disorders if the gene is switched on or off at the wrong time or in the wrong place.
While we cannot directly control which genes are switched on and off, we can influence the process through various means such as lifestyle choices, medication, and environmental factors. Additionally, advancements in genetic engineering and gene therapy are allowing scientists to manipulate gene expression more precisely, potentially offering new ways to treat diseases and disorders.