2013 Group 6 Project

From CellBiology

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Anaphase is an extremely important part of cell division yet is only around 1% of the cell cycle length. Anaphase differs slightly in meiosis and mitosis however the overall function remains the same. This part of cell division commences with the Metaphase to Anaphase transition (MAT) where by the Analhase promoting complex marks the inhibitory chaperone Securin" which inhibits the chromatids from early separation.

  • Chromosomes split
  • sister chromatids move to poles at opposite ends of cell

  • Importance of Anaphase in living replicating organisms[1]


Date Description
1871 Alexander Kowalevski was the first to comprehend and then figure out the achromatic spindle function.[1]
1879 Walter Flemming discovered the longitudinal splitting of chromosomes when in mitosis.[2]
1925 Edmund Beecher Wilson published a timeless work in a book titled "The Cell in Development and Heredity". This book compares the different stages of the cell mitotic cycle and identifies this division process within different organisms specifically contributing to anaphase understanding. [3]
1943 Hans Ris Uniquely used live imaging as opposed to photographs and identified two stages in anaphase firstly the shrinking as the chromosomes approach the poles and then the elongating as they move further apart.[4]


Metaphase to anaphase transition (MAT)

Metaphase to Anaphase transition

Metaphase-to-anaphase transition is tightly controlled by anaphase-promoting complex (APC) motions. APC promotes the degradation of several proteins that inhibit anaphase.[2] The regulatory protein Cdc20 triggers APC/C at the start of the metaphase-anaphase transition. Cdh1 a membrane protein which is able to control the fate of certain cells along with triggering anaphase through the G1 stage of the cell cycle. APC/C specifically targets securin(anaphase inhibitor), Early destruction of this inhibitor is coordinated by nuclear transport factors(Nup98 and Rae1), This mechanism is strictly governed to guarantee appropriate timing of degradation. [3] Mistakes during this process can cause segregation problems leading to the possible demise of the organism. [5]

Process of sister chromatid separation

Sister chromatid separation during anaphase is considered one of the main process of cell division. The chromatids follow a similar path of separation in both meiosis and mitosis. The force of the spindle within the cell stretches the chromatids substantially without detaching which indicates they are physically unable to separate at that point in time. In order for the chromatids to be joined or cohesed together originally, the protein cohesin is employed with the sub units differing between species. Without the cohesion of the chromatids they would be able to separate in any stage of mitosis or meiosis, however the timing of separation is critical for the ultimate survival and correct progression of the cell and organism.

Cohesin binds along various points on the arms of the chromosome (this is dissolutioned during prophase) as well as the centromeric region (the part of the chromosome which includes the centromeric DNA and corresponding proteins [4]. When chromatid segregation occurs, the cohesin protein must therefore be removed to ensure the correct chromatids are segregated to their poles by the spindle fibres. The sororin protein is considered to be one of the main controllers of the sister chromatid separation[5]. It regulates the cohesion of the chromatids by stabilising the cohesin protein to the sister chromatids. Securin, which is involved in the metaphase-anaphase transition, breaks down the cohesin between the two chromatids [6].

In mitosis, the separation of the cohesin is dependent upon the protein separin which is thought to be situated at the mitotic spindle, in the cytoplasm as well as the nucleus. In turn, separin is inhibited by securin (allowing the cohesin to remain intact for that time) and it is then ubiquinated (destroyed by ubiquitin) and separin is able to uncleave the cohesin [7]. Separin has been found to cleave the Scc1/Med1 component of cohesin however the way in which this occurs is currently unknown. Once the cohesin has been cleaved, the sister chromatids are able to be pulled towards the different poles by the spindle fibres [8].

Anaphase to telophase

Metaphase to Anaphase transition

Essentially the transition from Anaphase to telophase can take 2 pathways, the conventional or normal pathway involves the co-ordination of Kinetochore and microtubules attachment with the strict dictation from the spindle assembly checkpoint (SAC) where as the other route is basically a "short cut" by passing this checkpoint through a process known as mitotic slippage. The kinetochore is a specific zone located on the chromosomes centromeres. [9] During Anaphase chromatids are pulled apart by the microtubules attached to the kinetochore in the direction of the opposite poles. The organisation of these microtubules is critical for regulation of this phase. [10] Anaphase is defined by the the chromatids separating to become a daughter chromosomes. [11] The SAC is solely responsible for the inhibition of telophase initiation. This checkpoint acts as a government arresting cell processes if there is inadequate supply of kinetochore-microtubule attachments. [12]It should be noted that there are cellular processes that can override and bypass this government through mitotic slippage allowing anaphase lateral entry into telophase. [13]



Spindle fibers

Kinetochore is a proteinaceous structure that gathered at the chromosomal centromere region.[14][15][16] The functions of kinetochores are to facilitate the physical connection between the chromosomes and the spindle microtubules, and also to ensure accurate chromosome separation during anaphase. [17][18][19] During anaphase, kinetochores that are attached to the spindle microtubules are thought to induce a poleward forces to the chromosomes, which causes the chromosomes to move towards the opposite poles. [20][21]


Meiotic cell like oocytes does not contain centrosomes[22][23]. It is found that the kinetochores fibers are not involved in the development of the 1st meiotic spindle or in the meiotic chromosome assembly to the metaphase plate[24]. Instead, the meiotic spindle is gathered around the chromatin through a RanGTP –dependent pathway[25][26]. But, it is discovered that microtubules can self-organize into bipolar spindles if the chromatin in absent (8684481)(17276346) through motor-driven processes[27][28]. The drawback of non-kinetochore cell division is that it displays a random monopolar poleward action, which resembles chromosome nondisjunction during the error-prone meiosis[29][30]. Consequently, this may cause the formation of the aneuploidy cell [31]

Chromosomal motors

Plus-end directed motors

These motors are found at the chromosome arms. They are responsible for the “polar ejection” forces that help in positioning chromosomes at the spindle equator during chromosome congression, and they can also generate forces that help to sustain chromosome movement. [32][33]

Minus-end directed motors

Dynein a minus-end directed motor is mostly found in the kinetochores & the spindle poles [34][35]. Spindle-associated dynein aid in the assembling of spindle.[36][37][38] Kinetochore-associated dynein (KD) is needed to stabilize the connection between kinetochores and microtubules by generating tension on the kinetochore. In addition, KD also plays a role in silencing the spindle-assembly checkpoint (SAC)[39] that function in making sure that the chromosome separation prerequisites have been met and thus decides whether implement or delay the chromosome separation.[40]. Absence or decrease in KD may lead to failure of chromosome congression and reduction in chromosome velocity by ~40% during anaphase, without disturbing the poleward microtubules flux rate. [41]

Meiosis versus mitosis

Anaphase in meiosis

meiosis I

  1. Spindle fibres (attached to the chromatids in metaphase I) pull the two chromosomes apart and move them towards the opposite end of the poles.
  2. Note that in this stage, the sister chromatids are attached at the centromere.

meiosis II

  1. The spindle fibres attach to the chromatids and pull each chromatid to opposite ends of the pole.

Anaphase in mitosis

  1. Segregation of sister chromatids
  2. Sister chromatids move towards respective poles of the cell, driven by spindle action
  3. At the end of anaphase, each pole of the cell will have a complete set of chromosomes.

Molecular aspect of anaphase


Cdk1 is a gene from Ser/Thr protein kinase family. This gene assists in cell cycle regulation. Inactivation of this gene allows the formation of the pre-replicative complexes, which is important for DNA replication [42]. Partial activation of this gene might be required in anaphase during the segregation of the sister chromatids [43].Without the inactivation of Cdk1 gene, chromosomes cannot decondense, nuclear envelopes will not be able to reassemble and cell can’t divide [44][45][46]. This gene is inactivate via cyclin proteolysis mechanism[47].


APC/C is activated by binding of cdc20. This protein depends on high Cdk1 activity[48]. In anaphase, APC activity is needed but the APC’s role in cyclin proteolysis is not sufficient to justify its role in commencing anaphase. In order to initiate anaphase, it is crucial for at least one other APC substrate (such as securin) is destroyed[49].


Separase is a cysteine protein. It is essential in assisting the segregation of sister chromatids. This protein is activated by the proteolysis of securin that is mediated by APC/C. [50]

Cyclin B & Securin

Cyclin b and securin are both the substrate of APC/C. Both the proteins are stable until the initiation of metaphase. Cyclin b and securin degradation will only commence when all chromosomes have attached to the mitotic spindle. This process is mediated by APC/C. The reason is to ensure that the cohesin from sister chromatids are not dissolved before spindle assembly has been completed. Or else this will lead to the missegregation of the sister chromatids, which will cause the formation of aneuploid daughter cell.[51]


Cohesin connects the sister chromatids together. During the transition of metaphase to anaphase, the separase will cleaved the cohesin between the sister chromatids[52][53], which then cause sister chromatids to separate and move towards opposite spindle poles. In higher eukaryotes, like human, there are two different pathways in removing the cohesin[54]. The first pathway occurs during prophase and prometaphase. This pathway depends on Polo-like kinase mechanism[55][56][57]. During this pathway, majority of the cohesin is removed from chromosomes. The second pathway occurs during anaphase due to a small amount of cohesin remains on the chromosomes until the beginning of the anaphase that is normally found in the centromeric region [58][59]. This pathway occurs when separase is activated via APC-dependent securin proteolysis. It removes the remaining cohesin from the chromosome.

Spindle assembly checkpoint

Spindle assembly checkpoint is the biochemical pathway delays the proteolysis of securin & cyclin b until all chromosomes are bipolarly attached to the mitotic spindle [60]. A single unattached kinetochore is enough to delay all sister chromatids segregation [61]. This checkpoint is believed to measure the tension produced at kinetochore when both the sister chromatids are attached to the opposite poles.[62] [63]

Defects resulting from anaphase malformation


  • If the chromosome tips are damaged during anaphase then cytokinesis cannot occur[64] and therefore the cell cannot divide into two daughter cells, not sure if this is in relation to both mitosis and meiosis but should be interesting to further research. The experimental removal of chromosomal tips shows cell division being delayed, the furrow itself being delayed or even regressing from its ready to divide state.
Cytokinesis defects resulting from chromosomal tip damage during Anaphase
  • APC/C mutants of C. elegans demonstrate defects in germline proliferation, the development of the female vulva and male tail and the metaphase to anaphase transition in meiosis I. Therefore irregularities in the APC[65] contribute to physical deformities in this species. More on Metaphase-to-Anaphase (mat) transition abnormalities leading to defects in C. elegans here: [6]
  • The APC/C has many important roles in the development, function and survival of the nervous system[66]. Incorrect ACP activity leads to some neurological and psychiatric disorders. Research into the APC's role in neurobiology may grant us ways to use the APC to manage neurological disorders such as mental retardation and autism to even neurodegenerative disorders.
  • When the chromosomes do not separate properly in Anaphase, referred to as "nondisjunction"; aneuploidy results[67]. This refers to an abnormal number of chromosomes, with a well known one being Down's syndrome in which there are three copies of the 21st chromosome[68]. Down's syndrome is also called Trisomy 21 because it is a trisomic (cells with one extra chromosome, 2n+1) subtype of aneuploidy. Another type of trisomy is Patau syndrome (trisomy 13), which unfortunately kills children when they are only months old due to serious defects in the eyes, brain and circulatory system. Edward's syndrome (trisomy 13) similarly leaves children with only months to live as most of their organs are affected. The above mentioned chromosomal disorders pertain to aneuploidy in autosomes (non sex chromosomes, thus not the X or Y chromosomes which determine sex), however there are disorders which affect the allosomes (sex chromosomes). Klinefelter syndrome in males leads to unusual reproductive organs and sterility, as well as the overdevelopment of certain areas such as breasts which lead to feminine body features. Monosomic cells on the other hand are another subtype in which the cell has a missing chromosome (2n-2), this type is most commonly lethal in humans except for one; Turner's syndrome. In Turner's syndrome, females have only one X chromosome instead of the usual XX, females with this disorder do not mature sexually during puberty and are sterile, shorter and of average intelligence. More on chromosomes here: [7] and human chromosomal disorders here: [8]
  • Anaphase bridges can cause mutations such as the structural rearrangement of chromosomes which usually lead to the formation of isochromosomes (chromosomes which, after losing one of their arms are replaced with a copy of another arm) and whole-arm translocations, the loss of the entire chromosome through mitotic spindle detachment or faulty cytokinesis in which the failure to divide results in polyploidy (more than 2 copies of a chromosome) and additional centrosomes which may lead to multipolar spindle formations in future mitosis[69]. The presence of chromatin bridges in Anaphase is also linked to chromosomal instability[70] and cancer.
A model for how ultrafine anaphase bridges are formed and lead to centromeric non-disjunction
  • Centrosomes are specialized structures which mediate chromosome segregation during mitosis. Centromeric ultrafine anaphase bridges are organizations of unresolved DNA strings or catenations between the separating centromeres during anaphase. A study[71] has sought to understand how these bridges disassemble prior to anaphase onset, taking advantage of BLM and PICH helicases, proteins which aid in the colocalization of ultrafine anaphase bridges and promote their disassembly. As PICH is present at centromeres and easily visualized, an extensive range of microscopy techniques were employed in hopes of proving that BLM might also be present at centromeres and that both worked together to resolve DNA catenations before anaphase. It was found that cells which lacked BLM and PICH exhibited changes in their centromere structure, as well as higher rates of centromeric non-disjunction in cells which had no cohesin hinting at catenations which failed to separate. Results showed a relationship between BLM and PICH were important for complete and correct centromere disjunction and a model was proposed which demonstrated the combined effects of BLM and PICH in promoting the organization of centromeric chromatin allowing for the catenates to be easily reached by Topoisomerase IIa, a class of proteins which cut DNA strands in order to manage tangles and unwanted extra coils. This research has contributed to our understanding on how and why sufferers of Bloom's syndrome are more predisposed to cancer.

Current research


Correct division of cellular contents between two daughter cells depends upon spatial and temporal cues; anaphases' microtubular system organizes itself at the spindle midzone and functions to orient the cell division plane in the center of the segregating chromosomes. The signalling pathway responsible for this is not understood, but this molecular study[72] explores how the phosphorylation of Aurora B kinase; a regulator of mitosis, ultimately leads to a gradient which centers at the spindle midzone. The study is therefore successful in the discovery of a possible regulatory mechanism for the anaphase phosphorylation gradient, and suggests that its findings may be useful in the future development of a model for anaphases' spatial patterning.

The Anaphase Promoting Complex/Cyclosome or APC/C moderates mitosis by adding ubiquitin chains to cell cycle regulators, to initiate the formation of these chains the APC/C binds ubiquitin to lysine in substrates and elongates chains via lysine residue modification in attached ubiquitin moieties. How the APC/C and ubiquitin ligases are able to change from lysine residues present on substrates to specific ones on ubiquitin is not known, however; recently the method of assembly for the ubiquitin chains that control the APC/C has been determined. It has been found that by the assembly of certain ubiquitin chains the APC/C initiates substrate degradation, a study[73] has hypothesised that via the APC/C's ability to identify patterns in substrates and ubiquitin allows it to build ubiquitin chains that are able to tightly regulate the cell cycle.


Kinetochores are important structures whose role it is to connect the segregating chromosomes to the spindle microtubules during mitosis. How the meiotic spindle creates the poleward forces to allow for double mitosis resulting in haploid chromosomes is not completely understood, however this study[74] explores how since the DNA beads formed are able to promote the formation of a bipolar spindle they had no need for kinetochores. Dynein, a motor protein which allows for transport of cellular cargo, was thought to have been the culprit. However even after this protein was located and its function ceased, it was noticed that the DNA beads no longer moved towards the poles, but the chromosomes still did. This suggested the possibility of dynein-dependant and dynein-independent poleward movement mechanisms, with the dynein-independent possibly being reliant on the kinetochores.

(A) DNA bead and chromosomal poleward movement during anaphase II in meiosis, (B) Timelapse of an oocyte undergoing anaphase


A recent study[75] investigating the origins of the wait-anaphase signal has concluded that there may be more than one mechanism however they are not fully understood. The researchers have proposed that when the Ndc80 nears Aurora B, it produces unbound kinetochores through the reduction of their affinity to bind to microtubules. The other proposed mechanism is via a conformational change in the Mis12 complex which may move the Ndc80 complex closer to KNL-1 within the KMN network such that it catalyzes the assembly of the MCC.


The Anaphase Catastrophe is a programmed cellular death mechanism (apoptotic) that targets tumour cells that have more than two centrosomes. Tumour cells are able to live with their abnormal number of centrosomes due to a clustering of their centrosomes thanks to special pathways, which allow them to keep the bipolar chromosome segregation seen in normal division. These abnormal cells can then proceed to anaphase with their multipolar spindles and segregate their chromosomes to an unusual number of daughter cells (more than two). All resulting daughter cells will subsequently die; hence this is what is known as anaphase catastrophe. Because it is an intrinsic targeting system for tumour cells, it has been suggested that it may be a target for cancer therapy[76] and warrants further future research. The anaphase catastrophe has demonstrated this ability to interrupt and inhibit the growth and development of malignant cells in this study on lung cancer growth [9]

  • Figure 2 image from ^ paper is a good image to use for this section, but it has NO COPYRIGHT NOTICE???

Suggested research

Contractile forces

It has been known for quite some time that due to the extension of the anaphase spindle, spherical tissue cultured cells will elongate to a capsular shape while preparing for cytokinesis. A study[77] has based itself on further understanding the process of anaphase cell elongation, however it is noted that the functions of equatorial contraction, polar relaxation, and the spindle pushing force remain unknown. Whether cell elongation is a phase in its own right or part of another, and how these cellular processes are controlled are not understood.

APC structure & purpose of mitotic phosphorylation

So far, there have not been any successful vertebrate Anaphase Promoting Complex/Cyclosome (APC/C) reconstitutions from recombinant subunits[78] in vitro and thus the purpose of the multiple mitotic phosphorylations it undergoes as well as what kinases are involved remains a target for study. Current study is therefore limited to APC phosphorylation in vitro in comparison with APC modification in vivo, advances have however been made in the effects of regulation via phosphorylation of CDC20, which is a protein complex associated with the APC which serves to activate it.

Anaphase inhibitors as DNA integrity checkpoints during cell division

Research conducted on Saccharomyces cerevisiae has shown that it is damage induced to the DNA, and not the suppression of DNA replication which leads to the phosphorylation of securin Pds1p; an anaphase inhibitor which prevents anaphase from progressing. This study[79] notes the importance of this in terms of cell division, and suggests its possibility of being a DNA damage checkpoint in mitosis.

Further reading

  • Differences between meiosis and mitosis [10]
  • More on anaphase defects [11]
  • Mutations in subunits of the APC/C [12]
  • Anaphse spindle and its role in the prevention of chromosomal mis-segregation [13]
  • Kinetochores, spindles and cell death [14]


  • Anaphase Promoting Complex/ Cyclosome (APC/C) - A large protein complex of multiple subunits which activates during cell division and whose purpose it is to signal for anaphase to begin.
  • Cell cycle - The series of events that occur within a cell during its lifetime; divided into phases of growth, replication and division into daughter cells.
  • Chromosome - blah
  • Chromatin bridges - blah
  • Chromatids - blah
  • Chromosome centromere - blah
  • Cytokinesis - The final stage of cell division in both meiosis and mitosis, wherein the cytoplasm of a dividing cell is constricted so that the cell may separate into the products of cellular division, the daughter cells.
  • Kinetochores - blah
  • KMN network: - Along with the more recently discovered Ska complex (consisting of Ska 1-3 subunits) oversee microtubule (MT) attachment to kinetochores (KT), and are thus crucial to proper mitotic division. The KMN is named according to the first letters in KNL1[15], Mis12[16], and Ndc80[17], which are proteins that assist in cell division and constitute the KMN network.
  • Meiosis - One of the two types of cellular division, a reductive type in which the daughter cells, also known as gametes (in males they are sperm cells and in females they are egg cells) are produced. The daughter cells have half the number of chromosomes of the parent cell and are thus termed haploid. Meiosis can be likened to a sort of double mitosis, with the phases being: Interphase, Prophase I, Metaphase I, Anaphase I, Telophase I, Prophase II, Metaphase II, Anaphase II and Telophase II. Four sperm/egg cells are produced which are genetically different to their parent cell with each successful meiotic division, when these cells fuse during sexual reproduction an embryo is created and later develops into a new organism. Oskar Hertwig, a German zoologist, first observed the importance of gametes. [18]
  • Microtubule - blah
  • Mitosis - The other type of cell division, all other cells that are not gametes (somatic cells) undergo mitosis in order to replicate. Cells in the human body replicate in order to reproduce resulting in growth or to repair damaged tissues. Mitosis results in two daughter cells that are genetically identical to the parent cell. No crossing over occurs and the daughter cells are diploid, meaning that they have the exact same number of chromosomes as the parent cell. Daughter cells are therefore essentially clones as the parent cell simply replicates its genetic material and splits into two cells.
  • Phosphorylation - The attachment of a phosphate (PO4) group to a protein or other organic molecule. Usually catalyzed by proteins, the phosphorylation and dephosphorylation (the removal of a PO4 group) usually activate or deactivate the proteins or molecules they're bound to.


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2013 Projects: Group 1 | Group 2 | Group 3 | Group 4 | Group 5 | Group 6 | Group 7

Dr Mark Hill 2013, UNSW Embryology ISBN: 978 0 7334 2609 4 - UNSW CRICOS Provider Code No. 00098G