Immortal DNA strand hypothesis
Encyclopedia
The immortal DNA strand hypothesis was proposed in 1975 by John Cairns
as a mechanism for adult stem cells to minimize mutations in their genomes. This hypothesis proposes that instead of segregating their DNA
during mitosis
in a random manner, adult stem cells divide their DNA asymmetrically, and retain a distinct template set of DNA strands (parental strands) in each division. By retaining the same set of template DNA strands, adult stem cells would pass mutations arising from errors in DNA replication
on to non-stem cell daughters that soon terminally differentiate
(end mitotic divisions and become a functional cell). Passing on these replication errors would allow adult stem cells to reduce their rate of accumulation of mutations that could lead to serious genetic disorder
s such as cancer
.
Although evidence for this mechanism exists, whether it is a mechanism acting in adult stem cells in vivo
is still controversial.
s are used to detect immortal DNA strand segregation: label-retention and label-release pulse/chase assays.
In the label-retention assay, the goal is to mark 'immortal' or parental DNA strands with a DNA label such as tritiated thymidine
or bromodeoxyuridine
(BrdU). These types of DNA labels will incorporate into the newly-synthesized DNA of dividing cells during S phase
. A pulse of DNA label is given to adult stem cells under conditions where they have not yet delineated an immortal DNA strand. During these conditions, the adult stem cells are either dividing symmetrically (thus with each division a new 'immortal' strand is determined and in at least one of the stem cells the immortal DNA strand will be marked with DNA label), or the adult stem cells have not yet been determined (thus their precursors are dividing symmetrically, and once they differentiate into adult stem cells and choose an 'immortal' strand, the 'immortal strand' will already have been marked). Experimentally, adult stem cells are undergoing symmetric divisions during growth and after wound healing, and are not yet determined at neonatal stages. Once the immortal DNA strand is labelled and the adult stem cell has begun or resumed asymmetric divisions, the DNA label is chased out. In symmetric divisions (most mitotic cells), DNA is segregating randomly and the DNA label will be diluted out to levels below detection after five divisions. If, however, cells are using an immortal DNA strand mechanism all the labeled DNA will continue to co-segregate to the adult stem cell, and after five (or more) divisions will still be detected within the adult stem cell. These cells are sometimes called label-retaining cells (LRCs).
In the label-release assay, the goal is to mark the newly synthesized DNA that is normally passed on to the daughter (non-stem) cell. A pulse of DNA label is given to adult stem cells under conditions where they are dividing asymmetrically. Under conditions of homeostasis
, adult stem cells should be dividing asymmetrically so that the same number of adult stem cells is maintained in the tissue compartment. After pulsing for long enough to label all the newly replicated DNA, the DNA label is chased out (each DNA replication now incorporates unlabeled nucleotides) and the adult stem cells are assayed for loss of the DNA label after two cell divisions. If cells are using a random segregation mechanism, then enough DNA label should remain in the cell to be detected. If, however, the adult stem cells are using an immortal DNA strand mechanism, they are obligated to retain the unlabeled 'immortal' DNA, and will release the all the labeled newly synthesized DNA to their differentiating daughter cells in two divisions.
Some scientists have combined the two approaches, by first using one DNA label to label the immortal strands, allowing to adult stem cells to begin dividing asymmetrically, and then using a different DNA label to label the newly synthesized DNA. Thus, the adult stem cells will retain one DNA label and release the other within two divisions.
Since these cells were cycling but continued to contain the BrdU label in their DNA, the researchers reasoned that they must be segregating their DNA using an immortal DNA strand mechanism. Joshua Merok et al. from the lab of James Sherley engineered mammalian cells with an inducible p53
gene that controls asymmetric divisions. BrdU pulse/chase experiments with these cells demonstrated that chromosomes segregated non-randomly only when the cells were induced to divide asymmetrically like adult stem cells. These asymmetrically dividing cells provide an in vitro model for demonstration and investigation of immortal strand mechanisms.
Scientists have strived to demonstrate that this immortal DNA strand mechanism exists in vivo in other types of adult stem cells. In 2005, Gilbert Smith published evidence that a subset of mouse mammary epithelial cells could retain DNA label and release DNA label in a manner consistent with the immortal DNA strand mechanism. Soon after, scientists from the laboratory of Derek van der Kooy showed that mice have neural stem cells that are BrdU-retaining and continue to be mitotically active. Asymmetric segregation of DNA was shown using real-time imaging of cells in culture. In 2006, scientists in the lab of Shahragim Tajbakhsh presented evidence that that muscle satellite cells
, which are proposed to be adult stem cells of the skeletal muscle
compartment, exhibited asymmetric segregation of BrdU-labelled DNA when put into culture. They also had evidence that demonstrated BrdU release kinetics consistent with an immortal DNA strand mechanism were operating in vivo, using juvenile mice and mice with muscle regeneration induced by freezing.
These experiments supporting the immortal strand hypothesis, however, are not conclusive. While the Lark experiments demonstrated co-segregation, the co-segregation may have been an artifact of radiation from the tritium. Although Potten identified the cycling, label-retaining cells as adult stem cells, these cells are difficult to identify unequivocally as adult stem cells. While the engineered cells provide an elegant model for co-segregation of chromosomes, studies with these cells were done in vitro with engineered cells. Some features may not be present in vivo or may be absent in vitro. In May 2007 evidence in support of the Immortal DNA Strand theory was discovered by Michael Conboy et al. , using the muscle stem/satellite cell model during tissue regeneration, where there is tremendous cell division during a relatively brief period of time. Using two BrdU analogs to label template and newly synthesized DNA strands, they saw that about half of the dividing cells in regenerating muscle sort the older "Immortal" DNA to one daughter cell and the younger DNA to the other. In keeping with the stem cell hypothesis, the more stemmy daughter typically inherited the chromatids with the older DNA, while the more differentiated daughter inherited the younger DNA.
Experimental evidence against the immortal strand hypothesis is sparse. In one study, researchers incorporated tritiated thymidine into dividing murine epidermal basal cells. They followed the release of tritiated thymidine after various chase periods, but the pattern of release was not consistent with the immortal strand hypothesis. Although they found label-retaining cells, they were not within the putative stem cell compartment. With increasing lengths of time for the chase periods, these label-retaining cells were located farther from the putative stem cell compartment, suggesting that the label-retaining cells had moved. However, finding conclusive evidence against the immortal strand hypothesis has proven difficult.
In 2002, he proposed that in addition to using immortal DNA strand mechanisms to segregate DNA, when the immortal DNA strands of adult stem cells undergo damage, they will choose to die (apoptose) rather than use DNA repair mechanisms that are normally used in non-stem cells.
Emmanuel Tannenbaum and James Sherley developed a quantitative model describing how repair of point mutation
s might differ in adult stem cells. They found that in adult stem cells, repair was most efficient if they used an immortal DNA strand mechanism for segregating DNA, rather than a random segregation mechanism. This method would be beneficial because it avoids wrongly fixing DNA mutations in both DNA strands and propagating the mutation.
However, this work has highly respected biologists among its detractors as exemplified by a further comment on a paper by the same authors from 2006. Available free online. But please also see the authors rebuttal of the criticism Available free online.
John Cairns (biochemist)
John Forster Cairns FRS is a British physician and molecular biologist who made significant contributions to molecular genetics, cancer research, and public health....
as a mechanism for adult stem cells to minimize mutations in their genomes. This hypothesis proposes that instead of segregating their DNA
DNA
Deoxyribonucleic acid is a nucleic acid that contains the genetic instructions used in the development and functioning of all known living organisms . The DNA segments that carry this genetic information are called genes, but other DNA sequences have structural purposes, or are involved in...
during mitosis
Mitosis
Mitosis is the process by which a eukaryotic cell separates the chromosomes in its cell nucleus into two identical sets, in two separate nuclei. It is generally followed immediately by cytokinesis, which divides the nuclei, cytoplasm, organelles and cell membrane into two cells containing roughly...
in a random manner, adult stem cells divide their DNA asymmetrically, and retain a distinct template set of DNA strands (parental strands) in each division. By retaining the same set of template DNA strands, adult stem cells would pass mutations arising from errors in DNA replication
DNA replication
DNA replication is a biological process that occurs in all living organisms and copies their DNA; it is the basis for biological inheritance. The process starts with one double-stranded DNA molecule and produces two identical copies of the molecule...
on to non-stem cell daughters that soon terminally differentiate
Cellular differentiation
In developmental biology, cellular differentiation is the process by which a less specialized cell becomes a more specialized cell type. Differentiation occurs numerous times during the development of a multicellular organism as the organism changes from a simple zygote to a complex system of...
(end mitotic divisions and become a functional cell). Passing on these replication errors would allow adult stem cells to reduce their rate of accumulation of mutations that could lead to serious genetic disorder
Genetic disorder
A genetic disorder is an illness caused by abnormalities in genes or chromosomes, especially a condition that is present from before birth. Most genetic disorders are quite rare and affect one person in every several thousands or millions....
s such as cancer
Cancer
Cancer , known medically as a malignant neoplasm, is a large group of different diseases, all involving unregulated cell growth. In cancer, cells divide and grow uncontrollably, forming malignant tumors, and invade nearby parts of the body. The cancer may also spread to more distant parts of the...
.
Although evidence for this mechanism exists, whether it is a mechanism acting in adult stem cells in vivo
In vivo
In vivo is experimentation using a whole, living organism as opposed to a partial or dead organism, or an in vitro controlled environment. Animal testing and clinical trials are two forms of in vivo research...
is still controversial.
Methods
Two main assayAssay
An assay is a procedure in molecular biology for testing or measuring the activity of a drug or biochemical in an organism or organic sample. A quantitative assay may also measure the amount of a substance in a sample. Bioassays and immunoassays are among the many varieties of specialized...
s are used to detect immortal DNA strand segregation: label-retention and label-release pulse/chase assays.
In the label-retention assay, the goal is to mark 'immortal' or parental DNA strands with a DNA label such as tritiated thymidine
Thymidine
Thymidine is a chemical compound, more precisely a pyrimidine deoxynucleoside. Deoxythymidine is the DNA nucleoside T, which pairs with deoxyadenosine in double-stranded DNA...
or bromodeoxyuridine
Bromodeoxyuridine
Bromodeoxyuridine is a synthetic nucleoside that is an analogue of thymidine. BrdU is commonly used in the detection of proliferating cells in living tissues....
(BrdU). These types of DNA labels will incorporate into the newly-synthesized DNA of dividing cells during S phase
S phase
S-phase is the part of the cell cycle in which DNA is replicated, occurring between G1 phase and G2 phase. Precise and accurate DNA replication is necessary to prevent genetic abnormalities which often lead to cell death or disease. Due to the importance, the regulatory pathways that govern this...
. A pulse of DNA label is given to adult stem cells under conditions where they have not yet delineated an immortal DNA strand. During these conditions, the adult stem cells are either dividing symmetrically (thus with each division a new 'immortal' strand is determined and in at least one of the stem cells the immortal DNA strand will be marked with DNA label), or the adult stem cells have not yet been determined (thus their precursors are dividing symmetrically, and once they differentiate into adult stem cells and choose an 'immortal' strand, the 'immortal strand' will already have been marked). Experimentally, adult stem cells are undergoing symmetric divisions during growth and after wound healing, and are not yet determined at neonatal stages. Once the immortal DNA strand is labelled and the adult stem cell has begun or resumed asymmetric divisions, the DNA label is chased out. In symmetric divisions (most mitotic cells), DNA is segregating randomly and the DNA label will be diluted out to levels below detection after five divisions. If, however, cells are using an immortal DNA strand mechanism all the labeled DNA will continue to co-segregate to the adult stem cell, and after five (or more) divisions will still be detected within the adult stem cell. These cells are sometimes called label-retaining cells (LRCs).
In the label-release assay, the goal is to mark the newly synthesized DNA that is normally passed on to the daughter (non-stem) cell. A pulse of DNA label is given to adult stem cells under conditions where they are dividing asymmetrically. Under conditions of homeostasis
Homeostasis
Homeostasis is the property of a system that regulates its internal environment and tends to maintain a stable, constant condition of properties like temperature or pH...
, adult stem cells should be dividing asymmetrically so that the same number of adult stem cells is maintained in the tissue compartment. After pulsing for long enough to label all the newly replicated DNA, the DNA label is chased out (each DNA replication now incorporates unlabeled nucleotides) and the adult stem cells are assayed for loss of the DNA label after two cell divisions. If cells are using a random segregation mechanism, then enough DNA label should remain in the cell to be detected. If, however, the adult stem cells are using an immortal DNA strand mechanism, they are obligated to retain the unlabeled 'immortal' DNA, and will release the all the labeled newly synthesized DNA to their differentiating daughter cells in two divisions.
Some scientists have combined the two approaches, by first using one DNA label to label the immortal strands, allowing to adult stem cells to begin dividing asymmetrically, and then using a different DNA label to label the newly synthesized DNA. Thus, the adult stem cells will retain one DNA label and release the other within two divisions.
Evidence
Evidence for the immortal DNA strand hypothesis has been found in various systems. One of the earliest studies by Karl Lark et al. demonstrated co-segregation of DNA in the cells of plant root tips. Plant root tips labeled with tritiated thymidine tended to segregate their labeled DNA to the same daughter cell. Though not all the labeled DNA segregated to the same daughter, the amount of thymidine-labeled DNA seen in the daughter with less label corresponded to the amount that would have arisen from sister-chromatid exchange. Later studies by Christopher Potten et al. (2002), using pulse/chase experiments with tritiated thymidine, found long-term label-retaining cells in the small intestinal crypts of neonatal mice. These researchers hypothesized that long-term incorporation of tritiated thymidine occurred because neonatal mice have undeveloped small intestines, and that pulsing tritiated thymidine soon after the birth of the mice allowed the 'immortal' DNA of adult stem cells to be labeled during their formation. These long-term cells were demonstrated to be actively cycling, as demonstrated by incorporation and release of BrdU.Since these cells were cycling but continued to contain the BrdU label in their DNA, the researchers reasoned that they must be segregating their DNA using an immortal DNA strand mechanism. Joshua Merok et al. from the lab of James Sherley engineered mammalian cells with an inducible p53
P53
p53 , is a tumor suppressor protein that in humans is encoded by the TP53 gene. p53 is crucial in multicellular organisms, where it regulates the cell cycle and, thus, functions as a tumor suppressor that is involved in preventing cancer...
gene that controls asymmetric divisions. BrdU pulse/chase experiments with these cells demonstrated that chromosomes segregated non-randomly only when the cells were induced to divide asymmetrically like adult stem cells. These asymmetrically dividing cells provide an in vitro model for demonstration and investigation of immortal strand mechanisms.
Scientists have strived to demonstrate that this immortal DNA strand mechanism exists in vivo in other types of adult stem cells. In 2005, Gilbert Smith published evidence that a subset of mouse mammary epithelial cells could retain DNA label and release DNA label in a manner consistent with the immortal DNA strand mechanism. Soon after, scientists from the laboratory of Derek van der Kooy showed that mice have neural stem cells that are BrdU-retaining and continue to be mitotically active. Asymmetric segregation of DNA was shown using real-time imaging of cells in culture. In 2006, scientists in the lab of Shahragim Tajbakhsh presented evidence that that muscle satellite cells
Satellite cells
Myosatellite cells or satellite cells are small mononuclear progenitor cells with virtually no cytoplasm found in mature muscle. They are found sandwiched between the basement membrane and sarcolemma of individual muscle fibers, and can be difficult to distinguish from the sub-sarcolemmal nuclei...
, which are proposed to be adult stem cells of the skeletal muscle
Skeletal muscle
Skeletal muscle is a form of striated muscle tissue existing under control of the somatic nervous system- i.e. it is voluntarily controlled. It is one of three major muscle types, the others being cardiac and smooth muscle...
compartment, exhibited asymmetric segregation of BrdU-labelled DNA when put into culture. They also had evidence that demonstrated BrdU release kinetics consistent with an immortal DNA strand mechanism were operating in vivo, using juvenile mice and mice with muscle regeneration induced by freezing.
These experiments supporting the immortal strand hypothesis, however, are not conclusive. While the Lark experiments demonstrated co-segregation, the co-segregation may have been an artifact of radiation from the tritium. Although Potten identified the cycling, label-retaining cells as adult stem cells, these cells are difficult to identify unequivocally as adult stem cells. While the engineered cells provide an elegant model for co-segregation of chromosomes, studies with these cells were done in vitro with engineered cells. Some features may not be present in vivo or may be absent in vitro. In May 2007 evidence in support of the Immortal DNA Strand theory was discovered by Michael Conboy et al. , using the muscle stem/satellite cell model during tissue regeneration, where there is tremendous cell division during a relatively brief period of time. Using two BrdU analogs to label template and newly synthesized DNA strands, they saw that about half of the dividing cells in regenerating muscle sort the older "Immortal" DNA to one daughter cell and the younger DNA to the other. In keeping with the stem cell hypothesis, the more stemmy daughter typically inherited the chromatids with the older DNA, while the more differentiated daughter inherited the younger DNA.
Experimental evidence against the immortal strand hypothesis is sparse. In one study, researchers incorporated tritiated thymidine into dividing murine epidermal basal cells. They followed the release of tritiated thymidine after various chase periods, but the pattern of release was not consistent with the immortal strand hypothesis. Although they found label-retaining cells, they were not within the putative stem cell compartment. With increasing lengths of time for the chase periods, these label-retaining cells were located farther from the putative stem cell compartment, suggesting that the label-retaining cells had moved. However, finding conclusive evidence against the immortal strand hypothesis has proven difficult.
Further models
After Cairns first proposed the immortal DNA strand mechanism, the theory has undergone several refinements.In 2002, he proposed that in addition to using immortal DNA strand mechanisms to segregate DNA, when the immortal DNA strands of adult stem cells undergo damage, they will choose to die (apoptose) rather than use DNA repair mechanisms that are normally used in non-stem cells.
Emmanuel Tannenbaum and James Sherley developed a quantitative model describing how repair of point mutation
Point mutation
A point mutation, or single base substitution, is a type of mutation that causes the replacement of a single base nucleotide with another nucleotide of the genetic material, DNA or RNA. Often the term point mutation also includes insertions or deletions of a single base pair...
s might differ in adult stem cells. They found that in adult stem cells, repair was most efficient if they used an immortal DNA strand mechanism for segregating DNA, rather than a random segregation mechanism. This method would be beneficial because it avoids wrongly fixing DNA mutations in both DNA strands and propagating the mutation.
Mechanisms
The complete proof of a concept generally requires a plausible mechanism that could mediate the effect. Although controversial, there is a suggestion that this could be provided by the Dynein Motor. This paper is accompanied by a comment summarizing the findings and background Available free onlineHowever, this work has highly respected biologists among its detractors as exemplified by a further comment on a paper by the same authors from 2006. Available free online. But please also see the authors rebuttal of the criticism Available free online.