S377 Chapter 17

Description

Quiz based on the summaries of chapter 17
Mikki M
Quiz by Mikki M, updated more than 1 year ago
Mikki M
Created by Mikki M about 8 years ago
5
0

Resource summary

Question 1

Question
Differentiation is the process by which cells become [blank_start]specialized[blank_end]; it involves a sequence of molecular events that result in differential [blank_start]gene expression[blank_end], which, in turn, determines the [blank_start]proteins[blank_end] that a cell will express.
Answer
  • specialized
  • gene expression
  • proteins

Question 2

Question
Differentiation takes place both during development and in mature tissues.
Answer
  • True
  • False

Question 3

Question
Animal development involves a series of overlapping processes. [blank_start]Cleavage[blank_end] divisions, which form the [blank_start]blastula[blank_end], are followed by [blank_start]gastrulation[blank_end], during which the three germ layers (ec[blank_start]toderm[blank_end], m[blank_start]esoderm[blank_end] and en[blank_start]doderm[blank_end]) are formed and specification of the n[blank_start]eurectoderm[blank_end] and the anterior–posterior axis take place. The neural tube forms during [blank_start]neurulation[blank_end], and body segmentation begins. Finally [blank_start]organogenesis[blank_end] and in some species, metamorphosis, occur.
Answer
  • Cleavage
  • blastula
  • gastrulation
  • toderm
  • esoderm
  • doderm
  • eurectoderm
  • neurulation
  • organogenesis

Question 4

Question
[blank_start]Differentiation[blank_end] involves molecules that are evolutionarily conserved between animal species, and act in different places and at different times during [blank_start]animal development[blank_end]. These molecules include [blank_start]transcription factors[blank_end], and a number of different secreted and cell surface [blank_start]signalling proteins[blank_end], their receptors and downstream intercellular signalling molecules. Differential exposure to signalling molecules results in [blank_start]differential activation[blank_end] of transcription factors, leading to [blank_start]differential gene expression[blank_end].
Answer
  • Differentiation
  • animal development
  • transcription factors
  • signalling proteins
  • differential activation
  • differential gene expression

Question 5

Question
Differentiation is studied by cell a[blank_start]blation[blank_end], cell t[blank_start]racing[blank_end], transplantation, genetic analysis and cell culture techniques.
Answer
  • blation
  • racing

Question 6

Question
Similar mechanisms are involved in differentiation of different cells and tissues, of all animal species studied. These mechanisms include [blank_start]asymmetric division[blank_end], cell interactions, protein and mRNA [blank_start]gradients[blank_end] and [blank_start]combinatorial[blank_end] control.
Answer
  • asymmetric division
  • gradients
  • combinatorial

Question 7

Question
Induction and patterning of the mesoderm, like that of other embryonic tissues, involves protein and mRNA gradients and combinatorial control.
Answer
  • True
  • False

Question 8

Question
Development of the cells of the nervous system involves a series of events, including neural [blank_start]induction[blank_end], [blank_start]neurulation[blank_end], patterning of the [blank_start]central nervous system[blank_end], neuronal [blank_start]differentiation[blank_end], migration of [blank_start]neural crest cells[blank_end] and [blank_start]axon guidance[blank_end].
Answer
  • induction
  • neurulation
  • central nervous system
  • differentiation
  • neural crest cells
  • axon guidance

Question 9

Question
In amphibians, neural induction involves inhibition of the action of BMP and Wnt proteins, by proteins that include [blank_start]Noggin[blank_end] and Frzb secreted by cells of the [blank_start]organizer[blank_end].
Answer
  • Noggin
  • organizer

Question 10

Question
Inhibition of [blank_start]BMP signalling[blank_end] in the presumptive [blank_start]neurectodermal[blank_end] cells results in [blank_start]downregulation[blank_end] of the transcription factor GATA-1 which drives [blank_start]epidermal[blank_end] differentiation, and activation of [blank_start]neural transcription factors[blank_end], including neurogenin and NeuroD.
Answer
  • BMP signalling
  • neurectodermal
  • downregulation
  • epidermal
  • neural transcription factors

Question 11

Question
Increased expression of the cell surface signalling protein [blank_start]Delta[blank_end] results in increased activation of its receptor, [blank_start]Notch[blank_end], and also of [blank_start]neurogenin[blank_end] in adjacent cells. This upregulation results in [blank_start]reduced[blank_end] reciprocal signalling from the adjacent cell, which stimulates [blank_start]increased[blank_end] expression of neurogenin in the first cell, which in turn promotes expression of the transcription factor [blank_start]NeuroD[blank_end], and subsequent [blank_start]neuronal differentiation[blank_end].
Answer
  • Delta
  • Notch
  • neurogenin
  • reduced
  • increased
  • NeuroD
  • neuronal differentiation

Question 12

Question
A dorso-ventral gradient in [blank_start]Hox gene[blank_end] expression along the developing nervous system provides positional information, which results in the formation of different [blank_start]regions[blank_end] along the anterior–posterior axis of the brain and [blank_start]spinal cord[blank_end].
Answer
  • Hox gene
  • regions
  • spinal cord

Question 13

Question
Different types of [blank_start]neuron[blank_end] are specified by expression of different [blank_start]regulatory genes[blank_end], induced by exposure to different levels of [blank_start]signalling molecules[blank_end], such as [blank_start]Shh[blank_end] and BMPs.
Answer
  • neuron
  • regulatory genes
  • signalling molecules
  • Shh

Question 14

Question
[blank_start]Neural crest[blank_end] cells give rise to a variety of cell types, including [blank_start]peripheral neurons[blank_end] and melanocytes. They arise from the neural tube, and undergo a transition from an [blank_start]epithelial[blank_end] to a mesenchymal state, which involves a change in expression of [blank_start]cadherins[blank_end] and other adhesion molecules. Neural crest cells [blank_start]migrate[blank_end] though the developing embryo along routes that are determined by cell surface molecules, ephrins, and by components of the [blank_start]extracellular matrix[blank_end].
Answer
  • Neural crest
  • peripheral neurons
  • epithelial
  • cadherins
  • migrate
  • extracellular matrix

Question 15

Question
The projections of growing axons are determined by [blank_start]guidance cues[blank_end]; both diffusible and [blank_start]contact-mediated[blank_end] signalling are involved. Proteins in the environment of the growing axon are detected by [blank_start]receptors[blank_end] expressed on the [blank_start]growth cone[blank_end]. Axons of [blank_start]commissural[blank_end] neurons, which cross the developing spinal cord, are first attracted by [blank_start]netrins[blank_end], and then their onwards trajectory is determined by [blank_start]repulsive[blank_end] signals from the proteins [blank_start]Slit[blank_end] and semaphorin.
Answer
  • guidance cues
  • contact-mediated
  • receptors
  • growth cone
  • commissural
  • netrins
  • repulsive
  • Slit

Question 16

Question
Differentiation occurs in some tissues throughout life. An example is that of [blank_start]intestinal[blank_end] epithelial cells, which form from a pool of [blank_start]stem cells[blank_end] in the intestinal [blank_start]crypts[blank_end].
Answer
  • intestinal
  • stem cells
  • crypts
  • villi

Question 17

Question
Adult [blank_start]stem cells[blank_end] exist in many [blank_start]differentiated[blank_end] tissues. Evidence suggests that their [blank_start]potential[blank_end] in vivo and in vitro may be broader than previously thought.
Answer
  • differentiated
  • stem cells
  • potential

Question 18

Question
[blank_start]Embryonic[blank_end] stem cells are derived from the inner cell mass of mammalian [blank_start]early embryos[blank_end]. They can be engineered in culture to produce specific cell types. They are [blank_start]totipotent[blank_end], and can differentiate into any kind of cell, unlike most [blank_start]adult[blank_end] stem cells which are only [blank_start]multipotent[blank_end], where they can differentiate into several different types of cell, but not all.
Answer
  • Embryonic
  • totipotent
  • adult
  • multipotent
  • early embryos

Question 19

Question
Some cells may be able to [blank_start]de-differentiate[blank_end], after injury in vivo , or as a result of manipulation in vitro. And then [blank_start]trans-differentiate[blank_end] into another type of cell. An example is a newt regrowing a limb.
Answer
  • de-differentiate
  • trans-differentiate

Question 20

Question
The [blank_start]transplantation[blank_end] of a nucleus from a fully or partially [blank_start]differentiated[blank_end] cell into an enucleated egg for the purpose of cloning requires [blank_start]reprogramming[blank_end] of the genetic material. (And it usually doesn't work!)
Answer
  • transplantation
  • differentiated
  • reprogramming
Show full summary Hide full summary

Similar

AQA Biology 8.1 structure of DNA
Charlotte Hewson
GCSE Biology B2 (OCR)
Usman Rauf
Biology Unit 2 - DNA, meiosis, mitosis, cell cycle
DauntlessAlpha
Cell Transport
Elena Cade
Function and Structure of DNA
Elena Cade
AQA Biology 12.1 cellular organisation
Charlotte Hewson
Haemoglobin
Elena Cade
BIOLOGY HL DEFINITIONS IB
Luisa Mandacaru
Key Biology Definitions/Terms
courtneypitt4119
The Circulatory System
Johnny Hammer
IB Biology Topic 4 Genetics (SL)
R S