Biology-Cell Division Flashcards Preview

DAT > Biology-Cell Division > Flashcards

Flashcards in Biology-Cell Division Deck (82)
Loading flashcards...
1
Q

How many phases does cell division consist of?

A

It consists of two phases, nuclear division followed by cytokinesis

2
Q

What does nuclear division divide?

A

It divides the genetic material in the nucleus

3
Q

What does the cytokinesis divide?

A

It divides the cytoplasm

4
Q

What are the two kinds of nuclear division?

A

Mitosis and Meiosis

5
Q

Mitosis

A

divides the nucleus so that both daughter cells are genetically identical

6
Q

Meiosis

A

reduction division, which produces genetically variable daughter cells that contain half the genetic info of the parent cell

7
Q

What’s the first step in either mitosis or meiosis?

A

The first step begins w/ the condensation of the genetic material, chromatin, into tightly coiled bodies called chromosomes

8
Q

Chromosomes is made up of two identical halves called _______________, which are joined at the _____________.

A

Chromosomes are made up of two identical halves called SISTER CHROMATIDS, which are joined at the CENTROMERE

9
Q

Each chromatid consists of a single, tightly coiled molecule of ________, the genetic material of the cell.

A

Each chromatid consists of a single, tightly coiled molecule of DNA, the genetic material of the cell.

10
Q

Describe a homologous pair of chromosomes

A

one homologue comes from the maternal parent, the other from the paternal parent

11
Q

How many chromosomes do humans have?

A

46 chromosomes, 23 homologous pairs, consisting of a total of 92 chromatids

12
Q

cell cycle

A

describes the sequence of events that occurs during the life of most eukaryotic cells

13
Q

interphase

A

the period during which the cell is not dividing; the chromatin is enclosed within a clearly defined nuclear envelope

Within the nucleus, one or more nucleoli are visible. Outside the nucleus, two microtubule organizing centers lie adjacent to one another.

In animals, each MTOC contains a pair of centrioles.

14
Q

What are the four phases of mitosis?

A

prophase, metaphase, anaphase, and telophase, followed by cytokinesis

15
Q

(Mitosis) Prophase

A

3 activities occur simultaneously:

First, the nucleoli disappear and the chromatin condense into chromosomes

Second, the nuclear envelope breaks down

Third, the mitotic spindle is assembled

Fourth, microtubules from each MTOC connect to a specialized region in the centromere called a kinetochore

16
Q

(mitosis) Metaphase

A

begins when the chromosomes are distributed across the metaphase plate. Metaphase ends when the microtubules, still attached to the kinetochores, pull each chromosome apart into two chromatids. Once separated from its sister chromatid, each chromatid is called a chromosome.

17
Q

(Mitosis) Anaphase

A

the microtubules connected to the chromatids (now chromosomes) shorten, effectively pulling the chromosomes to opposite poles. At the end of anaphase, each pole has a complete set of chromosomes, the same number of chromosomes as the original cell (Since they consist of only one chromatid, each chromosome contains only a single copy of the DNA molecule).

18
Q

(Mitosis) Telophase

A

concludes the nuclear division. During this phase, a nuclear envelope develops around each pole, forming two nuclei. The chromosomes within each of these nuclei disperse into chromatin, and the nucleoli reappear. Cytokinesis divides the cytoplasm to form two cells.

19
Q

How are plant and animal cell cytokinesis different?

A

Cell Plate- In plants, vesicles originating from Golgi bodies migrate to the plane between the two newly forming nuclei. The vesicles fuse to form a cell plate, which subsequently becomes the plasma membranes for the 2 daughter cells. Cell walls develop between the membranes.

Cleavage furrow- In animals, microfilaments form a ring inside the plasma membrane between the two newly forming nuclei. As microfilaments shorten, they act like purse strings to pull the plasma membrane into the center, dividing the cell into 2 daughter cells. The groove that forms as the purse strings are tightened is called a cleavage furrow.

20
Q

What happens when mitosis and cytokinesis are completed and interphase begins?

A

the cell begins a period of growth that is divided into 3 phases: G1, S, and G2.

21
Q

Does growth occur in all phases: G1, S, and G2?

A

Yes; although you can associate G1 and G2 w/ growth and S w/ synthesis

22
Q

What happens in the S phase?

A

the second DNA molecule for each chromosome is synthesized. As a result of this DNA replication, each chromosome that appears at the beginning of the next mitotic division will appear as two sister chromatids

23
Q

What happens in the G2 phase?

A

materials for the next mitotic division are prepared

24
Q

Cell cycle

A

the time span through mitosis and cytokinesis, together referred to as the M phase, through G1, S, and G2

25
Q

diploid cell

A

a cell w/ 2 copies of every chromosome (designated by 2n)

26
Q

Meiosis

A

similar to mitosis, but meiosis consists of two groups of divisions, meiosis I and meiosis II

27
Q

Meiosis I

A

homologous chromosomes pair at the metaphase plate, and then the homologues migrate to opposite poles

28
Q

Meiosis II

A

chromosomes spread across the metaphase plate and sister chromatids separate and migrate to opposite poles.

29
Q

(Meiosis) Prophase I

A

the nucleolus disappears, chromatin condenses into chromosomes, the nuclear envelope breaks down, and the spindle apparatus develops. MT’s begin attaching to kinetochores.

Once the chromosomes are condensed, homologous chromosomes pair up (synapsis). These pairs of homologous chromosomes are variously referred to as tetrads (a group of four chromatids) or bivalents. During synapsis, corresponding regions along nonsister chromatids form close associations called chiasmata

30
Q

chiasmata

A

sites where genetic material is exchanged between nonsister homologous chromatids, a process called crossing over

31
Q

synaptonemal complex

A

protein structure that temporarily forms between homologous chromosomes: gives rise to a tetrad w/ chiasmata and crossover events

32
Q

(Meiosis) Metaphase I

A

homologous pairs are spread across the metaphase plate. Microtubules attached to the kinetochore of one member of each homologous pair. Microtubules from the other pole are connected to the second member of each homologous pair.

33
Q

(Meiosis) Anaphase I

A

begins when homologues within tetrads uncouple as they are pulled to opposite poles (disjunction)

34
Q

(Meiosis) Telophase I

A

nuclear membrane develops. Since daughter nuclei will have half the number of chromosomes, cells that they eventually form will be haploid.

Beginning in telophase I, the cells of many species begin cytokinesis and form cleavage furrows or cell plates, In other species, cytokinesis is delayed until after meiosis II. Also, a short interphase II may begin. In any case, no replication of chromosomes occurs during this period. Instead, part II of meiosis begins in both daughter nuclei.

35
Q

(Meiosis) Prophase II

A

the nuclear envelope disappears and the spindle develops. No chiasmata and no crossing over of genetic material as in prophase I

36
Q

(Meiosis) Metaphase II

A

the chromosomes align on the metaphase plate, but now with half number of chromosomes

37
Q

(Meiosis) Anaphase II

A

begins as each chromosome is pulled apart into two chromatids by the microtubules of the spindle apparatus. The chromatids (now chromosomes) migrate to their respective poles. Again, this is exactly what happens in mitosis except that now there is only half the # of chromosomes

38
Q

(Meiosis) Telophase II

A

the nuclear envelope reappears at each pole and cytokinesis occurs. The end result of meiosis is four haploid cells (chromosome makeup of each daughter cell designated by n).

Each cell contains half the number of chromosomes, and each chromosome consists of only one chromatid.

Later in interphase, a second chromatid in each chromosome is replicated, but the cell will still have only half the # of chromosomes.

39
Q

What is mitosis responsible for?

A

it occurs during growth and development of multicellular organisms and for repair of existing cells. Mitosis is also responsible for asexual reproduction, common among plants and single-celled organisms. Mitosis occurs in somatic cells, body cells.

40
Q

What does mitosis end with?

A

mitosis ends w/ 2 diploid daughter cells

41
Q

What does meiosis end with?

A

meiosis ends w/ 4 haploid daughter cells

42
Q

What is meiosis responsible for?

A

meiosis is responsible for producing gametes

43
Q

fertilization

A

fusing of an egg and sperm, gives rise to a diploid cell called a zygote

44
Q

What’s the chromosome number in a parent cell before division begins in mitosis and meiosis?

A

Mitosis- 46
Meiosis I- 46
Meiosis II-46

45
Q

What’s the chromatid number in a parent cell before division begins?

A

Mitosis-92
Meiosis I-92
Meiosis II- 92

46
Q

Does crossing over occur at prophase for mitosis and meiosis?

A

Mitosis- no
Meiosis I- yes
Meiosis II- no

47
Q

Does chromosome arrangement occur on metaphase plate?

A

Mitosis- Chromosomes line up
Meiosis I-Homologues pair
Meiosis II- Chromosomes line up

48
Q

What’s the number of chromosomes in each daughter nucleus?

A

Mitosis-46
Meiosis I-23
Meiosis II-23

49
Q

of chromatids in each daughter nucleus?

A

Mitosis-46
Meiosis I-46
Meiosis II-23

50
Q

of daughter cells at end of division?

A

Mitosis-2
Meiosis I-2
Meiosis II-4

51
Q

Chromosome notation for daughter cells?

A

Mitosis-2n
Meiosis I-n
Meiosis II-n

52
Q

Genome notation for daughter cells?

A

Mitosis-diploid
Meiosis I-haploid
Meiosis II-haploid

53
Q

Purpose of division?

A

Mitosis-cell replacement, organism growth, asexual reproduction
Meiosis I- sexual reproduction
Meiosis II- sexual reproduction

54
Q

genetics of daughter cells?

A

Mitosis-genetically identical (clones)
Meiosis I- genetically variable
Meiosis II- genetically variable

55
Q

type of cells where division occurs?

A

Mitosis- somatic cells
Meiosis I- reproductive cells (ovaries, testes, anthers)
Meiosis II- reproductive cells (ovaries, testes, anthers)

56
Q

type of cells produced?

A

Mitosis- somatic cells
Meiosis I- gametes: eggs, sperm, pollen
Meiosis II- gametes: eggs, sperm, pollen

57
Q

Human cells contain ___ chromosomes (___ homologous pairs)

A

46 chromosomes, 23 homologous pairs
Thus, 2n= 46
For human gametes, n=23

58
Q

What produces spores? (plants)

A

meiosis

59
Q

spores (plants)

A

haploid cells that divide by mitosis to become a multicellular haploid structure, the gametophyte

60
Q

sporophyte

A

gametes produced by the gametophyte by mitosis, fuse and produce a diploid cell that grows by mitosis

61
Q

alternation of generations

A

when both the gametophyte and sporophyte stages are multicellular; alternation of haploid and diploid stages

62
Q

genetic recombination

A

reassortment of genetic material that originates from: crossing over during prophase I, independent assortment of homologues during metaphase I (which chromosome goes into which cell), and random joining of gametes aka germ cells ( which sperm fertilizes which egg - genetic composition of gamete affects this)

63
Q

crossing over

A

during prophase I, nonsister chromatids of homologous chromosomes exchange pieces of genetic material. As a result each homologue no longer entirely represents a single parent

64
Q

Independent assortment of homologues

A

during metaphase I, tetrads of homologous chromosomes separate into chromosomes that go to opposite poles. Which chromosome goes to which pole depends upon the orientation of a tetrad at the metaphase plate.

65
Q

random joining of gametes

A

which sperm fertilizes which egg is to a large degree a random event. In many cases, however, this event may be affected by the genetic composition of a gamete.

For example, some sperm may be faster swimmers and have a better chance of fertilizing the egg

66
Q

What are two functional limitations for cell size that limit growth or influence the start of a new cell division?

A
  1. Surface-to-volume ratio (S/V) volume gets much larger when cells grow (4/3pi r^3) vs. SA (4pi r^2). When S/V is large, exchange becomes much easier. When S/V is small, exchange is hard, leads to cell death or cell division to increase SA
  2. Genome-to-volume ratio (G/V)- genome size remains constant throughout life; as cell grows, only volume increase. G/V will be small and thus exceed the ability of its genome to produce sufficient amts of regulator of activities. Some large cells (paramecium, human skeletal muscle) are multinucleated to deal with this.
67
Q

What influences the onset of cell division?

A
  1. Checkpoints
  2. Cyclin-dependent kinases (Cdk’s).
  3. Growth factors
  4. Density-dependent inhibition
  5. Anchorage dependence
68
Q

Checkpoints

A

at specific points during the cell cycle, the cell evaluates internal and external conditions to determine whether or not to continue through the cell cycle.
The G1 checkpoint
The G2 checkpoint
The M checkpoint

69
Q

The G1 checkpoint

A

occurs near the end of G1 phase. If conditions are not appropriate or if the cell is genetically programmed not to divide, the cell proceeds no further through the cell cycle, remaining in a an extended G1 phase (or G0 phase), never beginning the S or G2 phases (unless some internal or external cue initiates a resumption of the cell cycle)

aka restriction point, the most important one. At the end of G1 phase, if cell is not ready to divide it may arrest here (G0 phase- nerve and muscle cells remain here, rarely divide after maturing) and never procedd or wait until it is ready

70
Q

the G2 checkpoint

A

occurring at the end of the G2 phase of the cell cycle, evaluates the accuracy of DNA replication and signals whether or not to begin mitosis.

checks for sufficient mitosis promoting factor (MPF) levels to proceed

71
Q

the M checkpoint

A

occurring during metaphase, ensures that microtubules are properly attached to all kinetochores at the metaphase plate before division continues w/ anaphase.

72
Q

Cyclin-dependent kinases (Cdk’s)

A

Cdk enzymes activate proteins that regulate the cell cycle by attaching a phosphate group to them (phosphorylation). Cdk’s are themselves activated by the protein cyclin, a protein whose presence varies during the different phases of the cell cycle

73
Q

Growth factors

A

the plasma membranes of cells have receptors for external molecules, or growth factors, that stimulate a cell to divide. One such growth factor is produced by damaged cells, stimulating other cells to divide. More than 50 different growth factors are known

74
Q

Density-dependent inhibition

A

cells stop dividing when the surrounding cell density reaches a certain maximum

75
Q

anchorage dependence

A

most cells only divide when they are attached to an external surface, such as the flat surface of a neighboring cell (or the side of a culture dish)

76
Q

cancer

A

characterized by uncontrolled cell growth and division

77
Q

transformed cells

A

cells that have become cancerous, proliferate w/o regard to cell cycle checkpoints, density-dependent inhibition, anchorage dependence, and other regulatory mechanism.

78
Q

In what stage of mitosis does karyotyping occurs?

A

Metaphase

79
Q

Is more time spent in interphase or mitosis?

A

Interphase (>90%)

80
Q

How many steps does prophase I have?

A
  1. leptotene (chromosomes start condensing)
  2. zygotene (synapsis begins; synaptonemal complex forming)
  3. pachytene (synapsis complete, crossing over)
  4. diplotene (synatopnemal complex disappears, chiasma still present)
  5. diakinesis (nuclear envelope fragments, chromosomes complete condensing, tetrads ready for metaphase)
81
Q

fertilization/syngamy

A

fusion of two haploid gametes = diploid zygote

82
Q

Plant meiosis and mitosis

A

meiosis in sporangia produces spores (haploid); spores undergo mitosis to become multicellular (gametophyte) which are haploid (n) isnce psores are already haploid. The gametes fuse and produce a diploid cell (zygote 2n) that grows by mitosis to become sporophyte. Cells in sporophyte (sporangia) undergo meiosis to produce haploid spores which germinate and repeat life cycle.