S377 Chapter 13

Descripción

Quiz based on summaries and diagrams of chapter 13
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Resumen del Recurso

Pregunta 1

Pregunta
Sometimes cells communicate directly through [blank_start]gap junctions[blank_end], which connects the [blank_start]cytoplasm[blank_end] of the cells and allows small molecules to travel through. This is different from normal signalling. [blank_start]Contact-dependent[blank_end] signalling involves signalling molecules not being [blank_start]secreted[blank_end], but expressed on the [blank_start]plasma membrane[blank_end] of the cell, and picked up by [blank_start]receptors[blank_end] on the plasma membrane of another cell. For example, when [blank_start]antigens[blank_end] are presented to [blank_start]T cells[blank_end] in the [blank_start]immune system[blank_end].
Respuesta
  • gap junctions
  • cytoplasm
  • Contact-dependent
  • secreted
  • plasma membrane
  • receptors
  • antigens
  • T cells
  • immune system

Pregunta 2

Pregunta
Label the diagram
Respuesta
  • endocrine
  • paracrine
  • autocrine
  • endocrine
  • paracrine
  • autocrine
  • endocrine
  • paracrine
  • autocrine

Pregunta 3

Pregunta
[blank_start]Paracrine signalling[blank_end] affects local cells. Cells closer to the source react differently to those further away due to [blank_start]concentration gradients[blank_end]. Signalling molecules used are either rapidly taken up by target cells or degraded by [blank_start]extracellular enzymes[blank_end] to keep the effects limited to a small area. [blank_start]Autocrine signalling[blank_end] is an oddity, and may occur in [blank_start]tumour cells[blank_end] to allow them to keep growing inappropriately. Also happens in [blank_start]development[blank_end]. [blank_start]Endocrine signalling[blank_end] involves signalling cells very far away, with the signalling molecules often transported in the [blank_start]bloodstream[blank_end]. These signalling molecules are called [blank_start]hormones[blank_end] (though there is lots of variation) and are not [blank_start]water soluble[blank_end] so last longer than [blank_start]paracrine signalling molecules[blank_end]. [blank_start]Electrical signalling[blank_end] involves neurons, where the signal is transmitted electrically along [blank_start]axons[blank_end] before being turned into a chemical signal at [blank_start]synapses[blank_end], to cross the [blank_start]synaptic cleft[blank_end]. The chemicals signalling molecules are called [blank_start]neurotransmitters[blank_end] (these are also very varied).
Respuesta
  • Paracrine signalling
  • concentration gradients
  • extracellular enzymes
  • Autocrine signalling
  • tumour cells
  • development
  • Endocrine signalling
  • bloodstream
  • hormones
  • water soluble
  • paracrine signalling molecules
  • Electrical signalling
  • axons
  • synapses
  • synaptic cleft
  • neurotransmitters

Pregunta 4

Pregunta
Label the 4 main classes of receptors
Respuesta
  • ion-channel receptor
  • 7-helix transmembrane receptor (7TM)
  • RIEA
  • recruiter receptor

Pregunta 5

Pregunta
In a basic model of [blank_start]signal transduction[blank_end], a signalling molecule binds to a [blank_start]specific receptor[blank_end], and this activates a sequence (or web) of [blank_start]intracellular signalling molecules[blank_end] that spread the information to relevant parts of the cell, activating [blank_start]target molecules[blank_end], which effect a [blank_start]cellular response[blank_end].
Respuesta
  • signal transduction
  • specific receptor
  • intracellular signalling molecules
  • target molecules
  • cellular response

Pregunta 6

Pregunta
Signalling between cells can be contact dependent or via secreted signalling molecules. The latter comprise p[blank_start]aracrine[blank_end], a[blank_start]utocrine[blank_end], e[blank_start]ndocrine[blank_end] or electrical signalling.
Respuesta
  • aracrine
  • utocrine
  • ndocrine

Pregunta 7

Pregunta
There are four types of cell surface receptors: ion [blank_start]channel[blank_end] receptors, 7-[blank_start]helix transmembrane[blank_end] receptors, receptors with [blank_start]intrinsic enzymatic[blank_end] activity, and enzyme-associated ([blank_start]recruiter[blank_end]) receptors. Receptors with intrinsic [blank_start]transcriptional[blank_end] activity are mostly [blank_start]intracellular[blank_end].
Respuesta
  • channel
  • helix transmembrane
  • intrinsic enzymatic
  • recruiter
  • transcriptional
  • intracellular

Pregunta 8

Pregunta
Two basic categories of signalling molecules intervene in signal transduction, according to the spatial and temporal requirements of the signalling pathway. (a) Small diffusible signalling molecules (‘[blank_start]second messengers[blank_end]’) enable rapid signal [blank_start]amplification[blank_end] and a [blank_start]widespread[blank_end] cellular response. (b) Signalling [blank_start]proteins[blank_end] fulfil many roles (by virtue of protein–protein interaction and protein regulation), including signal [blank_start]integration[blank_end], modulation, t[blank_start]ransduction[blank_end] and a[blank_start]nchoring[blank_end] functions.
Respuesta
  • second messengers
  • amplification
  • widespread
  • proteins
  • integration
  • ransduction
  • nchoring

Pregunta 9

Pregunta
[blank_start]G proteins[blank_end] and proteins activated by [blank_start]phosphorylation[blank_end] on tyrosine, serine and/or threonine residues can act as [blank_start]molecular switches[blank_end].
Respuesta
  • G proteins
  • phosphorylation
  • molecular switches

Pregunta 10

Pregunta
The [blank_start]subcellular location[blank_end] of the signalling protein is critical to its [blank_start]function[blank_end], and this is aided by [blank_start]transient[blank_end] or preassembled [blank_start]signalling complexes[blank_end].
Respuesta
  • subcellular location
  • function
  • transient
  • signalling complexes

Pregunta 11

Pregunta
Specific binding of [blank_start]signalling proteins[blank_end] to each other is critical for the effective [blank_start]transduction[blank_end] of the signal. [blank_start]Binding domains[blank_end] allow transient binding to [blank_start]specific[blank_end] (often phosphorylated) amino acid sequences or to [blank_start]phospholipids[blank_end].
Respuesta
  • signalling proteins
  • transduction
  • Binding domains
  • specific
  • phospholipids

Pregunta 12

Pregunta
The dissociation constant (KD) describes the affinity between receptors and their ligands. (D is subscript!) The higher the value of KD , the [blank_start]lower[blank_end] the affinity of a receptor for its ligand.
Respuesta
  • lower
  • higher

Pregunta 13

Pregunta
Ligands are classed as agonists or antagonists. [blank_start]Agonists[blank_end] usually work by binding to the ligand binding site and [blank_start]promoting[blank_end] its [blank_start]active conformation[blank_end]. [blank_start]Antagonists[blank_end] bind to the receptor, but [blank_start]do not promote[blank_end] the switch to the active conformation. A single receptor may be able to bind several [blank_start]different ligands[blank_end], and a single ligand may be able to bind to [blank_start]several receptors[blank_end].
Respuesta
  • Agonists
  • promoting
  • active conformation
  • Antagonists
  • do not promote
  • different ligands
  • several receptors

Pregunta 14

Pregunta
[blank_start]Receptors[blank_end] comprise a limited number of [blank_start]structural motifs[blank_end], which determine [blank_start]binding affinity[blank_end] and specificity of receptor–ligand complexes. Some ligands bind to [blank_start]several receptors[blank_end] and some receptors bind to [blank_start]several ligands[blank_end].
Respuesta
  • Receptors
  • structural motifs
  • binding affinity
  • several receptors
  • several ligands

Pregunta 15

Pregunta
[blank_start]Acetylcholine[blank_end] is a good example of a ligand with two structurally different kinds of [blank_start]receptor[blank_end]. [blank_start]Nicotinic[blank_end] receptors are ion channels, which are found predominantly in [blank_start]skeletal muscle[blank_end], and are stimulated by nicotine. Nicotinic receptor [blank_start]antagonists[blank_end] include the toxins α -bungarotoxin and tubocurarine. Acetylcholine binds at two sites within the channel. [blank_start]Muscarinic[blank_end] receptors, in contrast, are [blank_start]7TM G protein-coupled receptors[blank_end], found (for example) in [blank_start]cardiac muscle[blank_end]. Muscarine acts as an [blank_start]agonist[blank_end], whereas [blank_start]atropine[blank_end] acts as an antagonist. Acetylcholine binds in the core region of the transmembrane helical segments.
Respuesta
  • Acetylcholine
  • receptor
  • Nicotinic
  • skeletal muscle
  • antagonists
  • Muscarinic
  • 7TM G protein-coupled receptors
  • cardiac muscle
  • agonist
  • atropine

Pregunta 16

Pregunta
[blank_start]Adrenalin[blank_end] has a range of structurally related [blank_start]7TM G protein-coupled receptors[blank_end], with different tissue distributions and different [blank_start]affinities[blank_end] for numerous agonists and antagonists. Adrenalin, like acetylcholine, binds in the [blank_start]core region[blank_end] of the receptor, though other GPCRs can be activated in a variety of ways.
Respuesta
  • Adrenalin
  • 7TM G protein-coupled receptors
  • affinities
  • core region

Pregunta 17

Pregunta
Mechanisms for [blank_start]receptor activation[blank_end] are varied and include [blank_start]conformational[blank_end] changes (ion-channel receptors and 7TM), [blank_start]homo- or heterodimerization[blank_end] (receptors with intrinsic enzymatic activity and recruiter receptors) or even proteolysis.
Respuesta
  • receptor activation
  • conformational
  • homo- or heterodimerization

Pregunta 18

Pregunta
For most [blank_start]7TM receptors[blank_end] (the exception being the Frizzled class of 7TM receptors), [blank_start]conformational change[blank_end] on ligand binding activates associated [blank_start]cytoplasmic G proteins[blank_end]. Hence, they are called ‘[blank_start]G protein-coupled receptors[blank_end]’.
Respuesta
  • 7TM receptors
  • conformational change
  • cytoplasmic G proteins
  • G protein-coupled receptors

Pregunta 19

Pregunta
Receptors with [blank_start]intrinsic enzymatic activity[blank_end] include [blank_start]receptor tyrosine kinases[blank_end], receptor serine–threonine kinases, receptor tyrosine phosphatases, and receptor guanylyl cyclases. Most RTKs are activated by [blank_start]dimerization[blank_end] on ligand binding, leading to [blank_start]autophosphorylation[blank_end] of the cytoplasmic portion of the receptor. [blank_start]Phosphorylated[blank_end] tyrosine residues serve as docking sites for SH2-containing signalling proteins, which also recognize sequence-specific flanking motifs.
Respuesta
  • intrinsic enzymatic activity
  • receptor tyrosine kinases
  • dimerization
  • autophosphorylation
  • Phosphorylated

Pregunta 20

Pregunta
[blank_start]Dimerization[blank_end] of [blank_start]recruiter receptors[blank_end] facilitates the interaction between the [blank_start]membrane-bound[blank_end] receptor and [blank_start]cytosolic proteins[blank_end] with intrinsic enzymatic activity such as [blank_start]kinases[blank_end].
Respuesta
  • Dimerization
  • recruiter receptors
  • membrane-bound
  • cytosolic proteins
  • kinases

Pregunta 21

Pregunta
Receptors can be [blank_start]inactivated[blank_end] by [blank_start]removal[blank_end] of the [blank_start]ligand[blank_end], or by receptor [blank_start]desensitization[blank_end], which can be by i[blank_start]nactivation[blank_end], by s[blank_start]equestration[blank_end] or by d[blank_start]egradation[blank_end] of the receptor.
Respuesta
  • inactivated
  • removal
  • ligand
  • desensitization
  • nactivation
  • equestration
  • egradation

Pregunta 22

Pregunta
Some [blank_start]signalling molecules[blank_end] can diffuse across the [blank_start]plasma membrane[blank_end], and so have [blank_start]intracellular[blank_end], rather than cell surface receptors. Small hydrophobic ligands such as [blank_start]steroid hormones[blank_end] bind to members of the [blank_start]nuclear receptor group[blank_end], which undergo [blank_start]conformational change[blank_end] and bind to specific [blank_start]DNA sequences[blank_end], stimulating [blank_start]transcription[blank_end] of target genes.
Respuesta
  • signalling molecules
  • plasma membrane
  • intracellular
  • steroid hormones
  • nuclear receptor group
  • conformational change
  • DNA sequences
  • transcription

Pregunta 23

Pregunta
Label the diagram of signalling through G protein-coupled receptors (GPCRs)
Respuesta
  • signalling molecule
  • 7TM receptor
  • inactive trimeric G protein
  • inactive target protein
  • conformation change on binding ligand
  • binds to trimeric G protein
  • GTP
  • GDP
  • α subunit
  • βγ complex
  • activated G protein subunits
  • relays signal downstream
  • α subunit binds and activates protein
  • Pi
  • GTPase activity (intrinsic or accessory)
  • inactivated α subunit and dissociation

Pregunta 24

Pregunta
Label the diagram of one type of signalling involving cAMP
Respuesta
  • signalling molecule
  • activated 7TM GPCR
  • activated adenylyl cyclase
  • activated α subunit of G protein
  • cyclic AMP (made from ATP)
  • inactive PKA
  • activated PKA
  • inactive CREB
  • activated, phosphorylated CREB
  • cAMP response element (CRE)

Pregunta 25

Pregunta
[blank_start]Heterotrimeric G proteins[blank_end] are tethered to the [blank_start]internal surface[blank_end] of the plasma membrane, and are activated by [blank_start]conformational change[blank_end] within [blank_start]7TM receptors[blank_end]. There are many different [blank_start]α subunits[blank_end] (and a few βγ subunits), which interact with [blank_start]different receptors[blank_end] and different [blank_start]effectors[blank_end]. The major targets of G proteins include ion [blank_start]channels[blank_end], [blank_start]adenylyl cyclase[blank_end] ([blank_start]activated[blank_end] by Gαs and [blank_start]inhibited[blank_end] by Gαi) and PLC- β (activated by Gαq).
Respuesta
  • Heterotrimeric G proteins
  • internal surface
  • conformational change
  • 7TM receptors
  • α subunits
  • different receptors
  • effectors
  • channels
  • adenylyl cyclase
  • activated
  • inhibited

Pregunta 26

Pregunta
[blank_start]Phosphatidylinositol (PI)[blank_end] is the precursor of a family of small lipid [blank_start]second messengers[blank_end]. The inositol ring can be further [blank_start]phosphorylated[blank_end] at positions 3, 4, and 5 by lipid kinases. [blank_start]PI 3-kinase[blank_end] specializes in phosphorylating the hydroxyl group at the [blank_start]3 position[blank_end], thus generating the active signalling molecules PI(3,4)P2 and PI(3,4,5)P3 . The [blank_start]phosphorylated 3 position[blank_end] is recognized as a docking site by [blank_start]PH domain-containing proteins[blank_end], thus providing a mechanism for signalling proteins to be recruited to the membrane.
Respuesta
  • Phosphatidylinositol (PI)
  • second messengers
  • phosphorylated
  • PI 3-kinase
  • 3 position
  • phosphorylated 3 position
  • PH domain-containing proteins

Pregunta 27

Pregunta
[blank_start]Phospholipase C enzymes[blank_end] (especially PLC- β , activated by [blank_start]G proteins[blank_end], and [blank_start]RTK-activated[blank_end] PLC- γ ) cleave PI(4,5)P2 to generate [blank_start]diacylglycerol (DAG)[blank_end] and inositol 1,4,5-triphosphate (IP3 ). DAG remains embedded in the [blank_start]membrane[blank_end], where it activates [blank_start]protein kinase C (PKC)[blank_end]. [blank_start]IP3[blank_end] diffuses through the cytosol, and opens [blank_start]IP3 -gated calcium channels[blank_end], releasing [blank_start]stored calcium[blank_end] into the cytosol.
Respuesta
  • Phospholipase C enzymes
  • G proteins
  • RTK-activated
  • diacylglycerol (DAG)
  • membrane
  • protein kinase C (PKC)
  • IP3
  • IP3 -gated calcium channels
  • stored calcium

Pregunta 28

Pregunta
The [blank_start]Ca2+ ion[blank_end] is an important [blank_start]second messenger[blank_end], which enters the cytosol from the [blank_start]extracellular space[blank_end] through specific channels on the plasma membrane, or is rapidly released from [blank_start]stores[blank_end] into the cytoplasm. Calcium channels include [blank_start]IP3 -gated[blank_end] calcium channels, [blank_start]voltage-[blank_end]dependent calcium channels, or ryanodine receptors in skeletal muscle cells. It activates numerous Ca2+ -dependent proteins, [blank_start]including PKC[blank_end], but many of its effects are mediated via [blank_start]calmodulin[blank_end], which has four allosteric Ca2+ binding sites. Ca2+ /calmodulin then binds to and regulates [blank_start]target proteins[blank_end], especially Ca2+ /calmodulin-dependent protein kinases ([blank_start]CaM kinases[blank_end]).
Respuesta
  • Ca2+ ion
  • second messenger
  • extracellular space
  • stores
  • IP3 -gated
  • voltage-
  • including PKC
  • calmodulin
  • target proteins
  • CaM kinases

Pregunta 29

Pregunta
[blank_start]Cyclic AMP (cAMP)[blank_end] is another important [blank_start]second messenger[blank_end], synthesized from [blank_start]ATP[blank_end] by [blank_start]adenylyl cyclase[blank_end] (which is activated or [blank_start]inhibited[blank_end] by different G protein subtypes). It can open cAMP-gated [blank_start]ion channels[blank_end], but it mediates many of its effects through cAMP-dependent protein kinase A ([blank_start]PKA[blank_end]), whose roles include regulating [blank_start]glycogen[blank_end] metabolism, and [blank_start]phosphorylation[blank_end] of a transcription factor ([blank_start]CREB[blank_end]) that binds to the [blank_start]cAMP response element (CRE)[blank_end].
Respuesta
  • Cyclic AMP (cAMP)
  • second messenger
  • ATP
  • adenylyl cyclase
  • inhibited
  • ion channels
  • PKA
  • glycogen
  • phosphorylation
  • CREB
  • cAMP response element (CRE)

Pregunta 30

Pregunta
[blank_start]Cyclic GMP[blank_end] is synthesized by guanylyl cyclase. Its targets include [blank_start]cGMP-gated[blank_end] ion channels and a [blank_start]cGMP-dependent kinase (PKG)[blank_end].
Respuesta
  • Cyclic GMP
  • cGMP-gated
  • cGMP-dependent kinase (PKG)

Pregunta 31

Pregunta
[blank_start]Ras[blank_end] is the archetypal [blank_start]monomeric[blank_end], or small, [blank_start]G protein[blank_end]. Ras classically operates downstream of [blank_start]growth factor receptors[blank_end]: Grb-2, an SH2/SH3-containing adaptor protein, binds to phosphotyrosines on the activated RTK, and recruits Sos to the membrane environment; Sos promotes GTP binding by Ras. [blank_start]Activated Ras[blank_end] has more than one target, including [blank_start]PI 3-kinase[blank_end], but its most important downstream pathway is the [blank_start]MAP kinase pathway[blank_end]. Activated Ras recruits [blank_start]Raf[blank_end] to the membrane, where it is activated and then [blank_start]phosphorylates[blank_end] MEK, which then phosphorylates ERK, a [blank_start]MAP kinase[blank_end]. These have multiple cytoplasmic and [blank_start]transcription factor[blank_end] targets involved in cell [blank_start]growth and division[blank_end] or differentiation.
Respuesta
  • Ras
  • monomeric
  • G protein
  • growth factor receptors
  • Activated Ras
  • PI 3-kinase
  • MAP kinase pathway
  • Raf
  • phosphorylates
  • MAP kinase
  • transcription factor
  • growth and division

Pregunta 32

Pregunta
[blank_start]Protein kinase families[blank_end] involved at various points in signalling pathways include [blank_start]receptor tyrosine kinases[blank_end] (for example, the EGF receptor), non-receptor [blank_start]tyrosine kinases[blank_end] (such as Src and JAK), serine[blank_start]–threonine kinases[blank_end] such as PKC, PKA, MAP kinases and the TGF receptor, and rare [blank_start]dual-specificity kinases[blank_end] such as MEK.
Respuesta
  • receptor tyrosine kinases
  • Protein kinase families
  • tyrosine kinases
  • –threonine kinases
  • dual-specificity kinases

Pregunta 33

Pregunta
[blank_start]Protein phosphatases[blank_end] dephosphorylate proteins, and are grouped according to their targets, as are protein kinases. They include protein tyrosine [blank_start]phosphatases[blank_end], [blank_start]serine–threonine[blank_end] phosphatases, and a few dual-specificity phosphatases.
Respuesta
  • Protein phosphatases
  • phosphatases
  • serine–threonine

Pregunta 34

Pregunta
The duration of ERK activity determines [blank_start]activation[blank_end] of different [blank_start]transcription factors[blank_end] (SRF/TCF for immediate early genes; AP-1 for other target genes).
Respuesta
  • activation
  • transcription factors

Pregunta 35

Pregunta
Label the signalling pathways
Respuesta
  • PKA pathway
  • CaM pathway
  • PKC pathway
  • MAP kinase pathway
  • PI 3-kinase pathway

Pregunta 36

Pregunta
Label the diagram
Respuesta
  • PLC- β is activated by a Gαq protein.
  • PLC-β cleaves PI(4,5)P2 into DAG and IP3
  • hydrophilic IP3 diffuses through cytosol
  • binds to IP3-gated calcium channels
  • activate PKC
  • hydrophobic DAG has fatty acyl chains
  • stays in membrane, activates PKC

Pregunta 37

Pregunta
Label the diagram
Respuesta
  • dimerization and autophosphorylation
  • phosphorylated tyrosine docking sites
  • proteins with SH2 domains bind

Pregunta 38

Pregunta
Label the MAP kinase pathway
Respuesta
  • RTK
  • Grb-2
  • Sos
  • Ras
  • Raf
  • MEK
  • ERK

Pregunta 39

Pregunta
Label the JAK-STAT pathway
Respuesta
  • Everything is inactive
  • tyrosine kinase-associated receptor
  • Type of cytokine
  • α-interferon induces dimerization
  • JAKs cross-phosphorylate
  • JAKs phosphorylate tyrosines on receptor
  • STATs bind, then phosphorylated by JAKs
  • STATs form dimers via SH2 domains
  • STATs go to nuke, initiate transcription

Pregunta 40

Pregunta
[blank_start]Glycogen[blank_end] metabolism is controlled by two enzymes, glycogen [blank_start]synthase[blank_end] (mediating glycogen synthesis) and [blank_start]phosphorylase[blank_end] (mediating glycogen breakdown).
Respuesta
  • Glycogen
  • synthase
  • phosphorylase

Pregunta 41

Pregunta
[blank_start]Three[blank_end] pathways converge in the regulation of [blank_start]glycogen synthase[blank_end]: cAMP/PKA and GSK-3β are [blank_start]negative[blank_end] regulators, whereas ISPK/PP1G [blank_start]positively[blank_end] regulate the activity of glycogen synthase.
Respuesta
  • Three
  • glycogen synthase
  • negative
  • positively

Pregunta 42

Pregunta
[blank_start]Insulin[blank_end] and adrenalin have opposite effects on glycogen [blank_start]synthesis[blank_end]: insulin [blank_start]promotes[blank_end] glycogen synthesis by activating ISPK/PP1G and by inhibiting GSK-3β by the [blank_start]PI3K/PKB[blank_end] pathway, whereas [blank_start]adrenalin[blank_end] inhibits glycogen synthase by the [blank_start]cAMP/PKA[blank_end] pathway.
Respuesta
  • Insulin
  • synthesis
  • PI3K/PKB
  • adrenalin
  • promotes
  • cAMP/PKA

Pregunta 43

Pregunta
Three pathways converge in the activation of [blank_start]phosphorylase[blank_end] by phosphorylase [blank_start]kinase[blank_end]: Ca2+ and [blank_start]PKA[blank_end] activate phosphorylase kinase, whereas [blank_start]PP1[blank_end] is a negative regulator.
Respuesta
  • phosphorylase
  • kinase
  • PKA
  • PP1

Pregunta 44

Pregunta
[blank_start]Acetylcholine[blank_end], adrenalin and [blank_start]glucagon[blank_end] promote [blank_start]glycogen[blank_end] breakdown, whereas [blank_start]insulin[blank_end] inhibits it.
Respuesta
  • Acetylcholine
  • glucagon
  • glycogen
  • insulin

Pregunta 45

Pregunta
[blank_start]Acetylcholine[blank_end] in skeletal muscle and [blank_start]adrenalin[blank_end] in liver activate [blank_start]phosphorylase[blank_end] kinase by a common mechanism, an increase in cytosolic [blank_start]Ca2+[blank_end] , although the effect of ACh is by [blank_start]voltage-dependent[blank_end] channels and that of adrenalin by [blank_start]IP3-gated Ca2+[blank_end] channels.
Respuesta
  • Acetylcholine
  • adrenalin
  • phosphorylase
  • Ca2+
  • voltage-dependent
  • IP3-gated Ca2+

Pregunta 46

Pregunta
[blank_start]Adrenalin[blank_end] in muscle and [blank_start]glucagon[blank_end] in liver activate [blank_start]phosphorylase[blank_end] kinase by a common mechanism, namely an increase in [blank_start]cytosolic cAMP[blank_end] and subsequent activation of [blank_start]PKA[blank_end]. In addition, PKA further activates phosphorylase kinase in skeletal muscle by inhibition of [blank_start]PP1[blank_end] either directly or indirectly.
Respuesta
  • Adrenalin
  • glucagon
  • phosphorylase
  • cytosolic cAMP
  • PKA
  • PP1

Pregunta 47

Pregunta
[blank_start]Insulin[blank_end] has an opposite effect to [blank_start]adrenalin[blank_end] on [blank_start]glycogen[blank_end] breakdown, namely the [blank_start]inhibition[blank_end] of glycogen breakdown by [blank_start]activation[blank_end] of the phosphorylase kinase inhibitor, [blank_start]PP1[blank_end].
Respuesta
  • Insulin
  • adrenalin
  • glycogen
  • inhibition
  • activation
  • PP1

Pregunta 48

Pregunta
Activated [blank_start]PI 3-kinase[blank_end] activates [blank_start]PKB/Akt[blank_end], which exerts a number of anti-apoptotic actions by [blank_start]phosphorylation[blank_end] of downstream proteins: (1) it phosphorylates [blank_start]Bad[blank_end], thereby promoting Bad’s [blank_start]sequestration[blank_end] by an adaptor protein (not shown); (2) it phosphorylates and thereby [blank_start]inhibits caspase 9[blank_end] (in humans); (3) it phosphorylates and thereby [blank_start]inhibits[blank_end] members of the Forkhead family of [blank_start]transcription factors[blank_end], which stimulate transcription of [blank_start]pro-apoptotic genes[blank_end]; and (4) it phosphorylates and thereby [blank_start]activates[blank_end] the transcription factor [blank_start]CREB[blank_end], which stimulates transcription of [blank_start]anti-apoptotic genes[blank_end].
Respuesta
  • PI 3-kinase
  • PKB/Akt
  • phosphorylation
  • sequestration
  • Bad
  • inhibits caspase 9
  • inhibits
  • transcription factors
  • pro-apoptotic genes
  • activates
  • CREB
  • anti-apoptotic genes
Mostrar resumen completo Ocultar resumen completo

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