deck_6654892 Flashcards

1
Q

Gene controls-

A

mechanisms that control when and how fast specific genes will be transcribed and translated, and whether gene products will be switched on or silenced

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2
Q

Prokaryotic control

A

Usually exhibit transcriptional level control by organizing related groups of genes into groups that can be rapidly turned on and off (operons)

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3
Q

Jacob and Monod-

A

discovered mutant E. coli strains in which a single genetic defect wiped out the activity of three enzymes that helped to digest lactose. Therefore- DNA coding sequences for all three enzymes must be linked together as a unit and controlled by a common mechanism

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4
Q

Operon-

A

an arrangement in which a promoter and a set of operators control access to more than one prokaryotic gene. no operons in eukaryotes.

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5
Q

Regulatory (or repressor) gene

A

produces a repressor protein- substance that can prevent gene expression by blocking the action of RNA polymerase. operon.

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6
Q

Promoter region

A

is a sequence of DNA that RNA polymerase can attach to in order to begin transcription. operon.

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7
Q

Operator region

A

can block the action of the RNA polymerase if the region is occupied by a repressor gene. operon.

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8
Q

Structural genes

A

Structural genes contain DNA sequences that code for several related enzymes that direct the production of an endproduct. operon.

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9
Q

diagram inducible operon

A

ok

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10
Q

repressed state

A

meaning that a repressor is bound to the operator region, preventing the transcription of genes that code for enzymes that break down the substance the operon targets.

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11
Q

inducible operon

A

if substance the operon targets is required to induce, or turn on the gene, this operon is said to be an inducible operon. substance is usually repressed, but when the substance is present, it acts as an allosteric regulator that combines with an allosteric site on the repressor, making the repressor inactive. When the repressor is inactive, RNA polymerase is able to transcribe the genes that produce the enzymes that break down substance.

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12
Q

repressible operon.

A

usually in induced state. these genes only stop producing enzymes in the presence of an active repressor

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13
Q

diagram repressible operon

A

ok

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14
Q

induced state

A

meaning that the regulatory gene produces an inactive repressor that does not bind to the operator

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15
Q

detail repressible operon

A

RNA polymerase transcribes the genes necessary to produce enzymes that synthesize substance the operon targets. However, if the bacteria is in regions of abundance of substance, it no longer needs to synthesize its own. Therefore, some substance reacts with the inactive repressor and makes it active. substance acts as a corepressor. This active repressor can now bind to the operator regions, preventing the transcription of the genes.

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16
Q

Negative control-

A

regulatory proteins slow down gene activity

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17
Q

Positive control

A

regulatory proteins enhance gene activities. Regulated by activator proteins that bind to DNA andstimulate more efficient transcription of the gene

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18
Q

Positive control–E. coli

A

E. coli cells will not typically break down lactose that much unless there is no glucose. If no glucose- an activator called CAP will bind to cAMP, a second messenger, which allows RNA polymerase to bind more efficiently.

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19
Q

Positive control diagram

A

ok

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20
Q

Eukaryotic Control

A

Do not normally form operons- instead, each gene its own has specific regulatory sequences

21
Q

Chemical modifications (eukaryotic)

A

type of transcriptional control. methylation- methyl groups (-CH 3 ) can be “painted” on parts of DNA to block access to the genes. Acetylation- acetyl groups (-CH 3 CO–) are attached to DNA to make the genes more accessible

22
Q

UPE–

A

upstream promoter element

23
Q

Promoter (TATA box)-

A

RNA polymerase binds here to begin transcription–always TATA sequence. part of regulatory molecules and control sites

24
Q

Transcription initiation site

A

where transcription begins. part of regulatory molecules and control sites

25
Q

regulatory molecules and control sites

A

type of transcriptional control.

26
Q

tata box diagram

A

ok

27
Q

Enhancers

A

DNA sequences that increase the rate of RNA synthesis. enhancer type of UPE . part of regulatory molecules and control sites

28
Q

Activators

A

(types of regulator proteins) can bind here and help activate transcriptionpart of regulatory molecules and control sites

29
Q

enhancer/activator diagram

A

ok

30
Q

Silencers

A

DNA sequences that turn off transcription by binding to proteins called repressors

31
Q

terminator sequence

A

at terminator sequence, transcription is completed and mRNA is released

32
Q

Post translational control

A

Allosteric enzymes regulate rate of metabolic pathways throughfeedback inhibition

33
Q

Proteolytic processing-

A

Post translational control. proteins are synthesized in inactive form but become active by removal of a portion of the polypeptide chain

34
Q

Post translational control–chemical modification

A

adding or removing functional groups to alter the activity of an enzyme

35
Q

Translational control-

A

mRNA can be destroyed by ribonuclease enzymes in order to control the number of protein molecules translated from it

36
Q

Chromosome Organization

A

part of transcriptional control. DNA wound tightly around histones prevent polymerases from accessing the genes; Inactive genes lie in heterochromatin; Active genes–euchromatin.

37
Q

heterochromatin

A

Inactive genes lie in compacted chromatin called heterochromatin. Heterochromatin is not transcribed- ex- Barr bodies.

38
Q

euchromatin

A

active genes lie in loosely packed chromatin called euchromatin.

39
Q

What makes histones lose their grip? (Chromosome Organization)

A

Acetylation can make histones lose their grip

40
Q

What blocks gene’s influnce on trait? (Chromosome Organization)

A

Methylation can block a gene’s influence on atrait

41
Q

Post- transcriptional control-

A

Introns are spliced out by snRNPs, Differential mRNA processing, Ribozymes, Nuclear envelope controls when mRNA reaches a ribosome

42
Q

Differential mRNA processing-

A

the same pre-mRNA can be spliced in different ways in different cells- one sequence can be an intron in one type of cell but an exon in another, producing different versions of mRNA

43
Q

Ribozyme

A

Ribozyme- some intron RNA’s can self-splice, acting as an enzyme to catalyze the splicing process

44
Q

Nuclear envelope controls when mRNA reaches a ribosome

A

mRNA can only pass through the nuclear pores if there are specific proteins attached to the mRNA, Proteins help move the mRNA to its specific location to be translated or stored, Each mRNA has its own proteins attached, coded for by the untranslated end of mRNA

45
Q

add stuff specifically about lac and trp

A

ok

46
Q

high glucose does what to production of cAMP?

A

inhibits it

47
Q

non eukaryotic transcriptional control

A

operons

48
Q

When can RNA polymerase initiate transcription?

A

RNA polymerase can only initiate transcription after various regulatory proteins called transcription factors have assembled on the chromosome.