Textbook Question
In the light micrograph below of dividing cells near the tip of an onion root, identify a cell in interphase, prophase, metaphase, anaphase, and telophase. Describe the major events occurring at each stage.
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Ch. 8 The Cellular Basis of Reproduction and Inheritance
Taylor, Simon, Dickey, Hogan10th EditionCampbell Biology: Concepts & ConnectionsISBN: 9780136538783
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Table of contents
- Ch. 1 Biology: The Study of Scientific Life19
- Ch. 2 The Chemical Basis of Life17
- Ch. 3 The Molecules of Cells21
- Ch. 4 A Tour of the Cell20
- Ch. 5 The Working Cell17
- Ch. 6 How Cells Harvest Chemical Energy18
- Ch. 7 Photosynthesis: Using Light to Make Food15
- Ch. 8 The Cellular Basis of Reproduction and Inheritance22
- Ch. 9 Patterns of Inheritance17
- Ch. 10 Molecular Biology of the Gene13
- Ch. 11 How Genes Are Controlled13
- Ch. 12 DNA Technology and Genomics23
- Ch. 13 How Populations Evolve17
- Ch. 14 The Origin of Species19
- Ch. 15 Tracing Evolutionary History18
- Ch. 16 Microbial Life: Prokaryotes and Protists16
- Ch. 17 The Evolution of Plant and Fungal Diversity15
- Ch. 18 The Evolution of Invertebrate Diversity13
- Ch. 19 The Evolution of Vertebrate Diversity18
- Ch. 20 Unifying Concepts of Animal Structure and Function11
- Ch. 21 Nutrition and Digestion16
- Ch. 22 Gas Exchange16
- Ch. 23 Circulation17
- Ch. 24 The Immune System16
- Ch. 25 Control of Body Temperature and Water Balance20
- Ch. 26 Hormones and the Endocrine System10
- Ch. 27 Reproduction and Embryonic Development12
- Ch. 28 Nervous Systems10
- Ch. 29 The Senses12
- Ch. 30 How Animals Move19
- Ch. 31 Plant Structure, Growth, and Reproduction9
- Ch. 32 Plant Nutrition and Transport12
- Ch. 33 Control Systems in Plants15
- Ch. 34 The Biosphere: An Introduction to Earth's Diverse Environments15
- Ch. 35 Behavioral Adaptations to the Environment12
- Ch. 36 Population Ecology15
- Ch. 37 Communities and Ecosystems14
- Ch. 38 Conservation Biology14
Taylor, Simon, Dickey, Hogan10th EditionCampbell Biology: Concepts & ConnectionsISBN: 9780136538783Not the one you use?Change textbook
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Taylor, Simon, Dickey, Hogan 10th EditionCh. 8 The Cellular Basis of Reproduction and InheritanceProblem 15
Taylor, Simon, Dickey, Hogan 10th EditionCh. 8 The Cellular Basis of Reproduction and InheritanceProblem 15Chapter 8, Problem 15
Discuss the factors that control the division of eukaryotic cells grown in the laboratory. Cancer cells are easier to grow in the lab than other cells.
Why do you suppose this is?
Verified step by step guidance1
Understand the cell cycle: Eukaryotic cell division is controlled by the cell cycle, which consists of interphase (G1, S, G2) and mitotic phase (M). The cell cycle is regulated by checkpoints that ensure proper growth, DNA replication, and division.
Identify key regulators: Cyclins and cyclin-dependent kinases (CDKs) are proteins that regulate the progression of the cell cycle. These molecules ensure that cells only divide when conditions are favorable, such as sufficient nutrients and proper DNA integrity.
Consider external factors: In laboratory conditions, eukaryotic cells require specific growth factors, nutrients, and environmental conditions (e.g., temperature, pH) to divide. These factors mimic the signals cells receive in their natural environment to promote division.
Understand cancer cell behavior: Cancer cells often bypass normal regulatory mechanisms, such as cell cycle checkpoints, due to mutations in genes like p53 or RB. This allows them to divide uncontrollably, even under suboptimal conditions, making them easier to grow in the lab compared to normal cells.
Relate to laboratory conditions: Cancer cells are less dependent on external growth factors and are more resistant to stress, which makes them more adaptable to laboratory environments. Their ability to proliferate without strict regulation is a key reason they are easier to culture.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Cell Cycle Regulation
The cell cycle is a series of phases that eukaryotic cells go through to divide and replicate. Regulation of this cycle is crucial, involving checkpoints that ensure proper progression and prevent uncontrolled division. Factors such as cyclins and cyclin-dependent kinases (CDKs) play significant roles in this regulation, and disruptions can lead to cancerous growth.
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Cell Cycle Regulation
Growth Factors
Growth factors are proteins that stimulate cell division and survival. In laboratory settings, the presence or absence of specific growth factors can significantly influence the proliferation of eukaryotic cells. Cancer cells often have altered signaling pathways that allow them to bypass the need for these factors, making them easier to culture compared to normal cells.
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Cellular Senescence
Cellular senescence is a state where cells cease to divide and enter a permanent growth arrest, often as a response to stress or damage. Normal somatic cells have a limited number of divisions due to telomere shortening, while cancer cells can evade senescence through mechanisms like telomerase activation, allowing them to proliferate indefinitely in laboratory conditions.
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Related Practice
Textbook Question
An organism called a plasmodial slime mold is one large cytoplasmic mass with many nuclei. Explain how such a 'megacell' could form.
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Textbook Question
Briefly describe how three different processes that occur during a sexual life cycle increase the genetic diversity of offspring.
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Textbook Question
Compare cytokinesis in plant and animal cells.
In what ways are the two processes similar?
In what ways are they different?
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Textbook Question
Sketch a cell with three pairs of chromosomes undergoing meiosis, and show how non-disjunction can result in the production of gametes with extra or missing chromosomes.
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Textbook Question
Suppose you read in the newspaper that a genetic engineering laboratory has developed a procedure for fusing two gametes from the same person (two eggs or two sperm) to form a zygote. The article mentions that an early step in the procedure prevents crossing over from occurring during the formation of the gametes in the donor's body. The researchers are in the process of determining the genetic makeup of one of their new zygotes. Which of the following predictions do you think they would make? Justify your choice, and explain why you rejected each of the other choices.
a. The zygote would have 46 chromosomes, all of which came from the gamete donor (its one parent), so the zygote would be genetically identical to the gamete donor.
b. The zygote could be genetically identical to the gamete donor, but it is much more likely that it would have an unpredictable mixture of chromosomes from the gamete donor's parents.
c. The zygote would not be genetically identical to the gamete donor, but it would be genetically identical to one of the donor's parents.
d. The zygote would not be genetically identical to the gamete donor, but it would be genetically identical to one of the donor's grandparents.
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