In the field of

cell biology Cell biology (also cellular biology or cytology) is a branch of biology that studies the structure, function, and behavior of cells. All living organisms are made of cells. A cell is the basic unit of life that is responsible for the living an ...

, the method of partial cloning (PCL) converts a fully differentiated ''old''

somatic cell A somatic cell (from Ancient Greek σῶμα ''sôma'', meaning "body"), or vegetal cell, is any biological cell forming the body of a multicellular organism other than a gamete, germ cell, gametocyte or undifferentiated stem cell. Such cells com ...

into a partially reprogrammed ''young'' cell that retains all the specialised functions of the differentiated ''old'' cell but is simply younger. The method of PCL reverses characteristics associated with old cells. For example, old, senescent, cells ''rejuvenated'' by PCL are free of highly condensed senescence-associated heterochromatin foci (SAHF) and re-acquire the proliferation potential of young cells. The method of PCL thus rejuvenates old cells without de-differentiation and passage through an embryonic, pluripotent, stage.

Method

PCL consists in introducing a somatic adult or senescent

cell nucleus The cell nucleus (pl. nuclei; from Latin or , meaning ''kernel'' or ''seed'') is a membrane-bound organelle found in eukaryotic cells. Eukaryotic cells usually have a single nucleus, but a few cell types, such as mammalian red blood cells, h ...

or entire cell with enlarged membrane pores in an (activated)

oocyte An oocyte (, ), oöcyte, or ovocyte is a female gametocyte or germ cell involved in reproduction. In other words, it is an immature ovum, or egg cell. An oocyte is produced in a female fetus in the ovary during female gametogenesis. The femal ...

and to withdraw this treated cell before its de-differentiation and first

cell division Cell division is the process by which a parent cell divides into two daughter cells. Cell division usually occurs as part of a larger cell cycle in which the cell grows and replicates its chromosome(s) before dividing. In eukaryotes, there ar ...

occurs. Thus, the progressive rejuvenation capability of the oocyte is used only temporarily in order to obtain a partial natural rejuvenation. PCL permits to envisage a chosen degree of partial rejuvenation in changing the duration of the introduction of the treated cell in the oocyte. Using PCL cell de-differentiation and its age reprogramming might be, at least partially, separable. Thus the existence of an isolated ageing clock would be confirmed at least during a certain part of the

cellular evolution Evolution of cells refers to the evolutionary origin and subsequent evolutionary development of cells. Cells first emerged at least 3.8 billion years agoSchopf, JW, Kudryavtsev, AB, Czaja, AD, and Tripathi, AB. (2007). ''Evidence of Archean l ...

and

involution Involution may refer to: * Involute, a construction in the differential geometry of curves * '' Agricultural Involution: The Processes of Ecological Change in Indonesia'', a 1963 study of intensification of production through increased labour inpu ...

Application

First experimental result shows a possible high efficiency in partial rejuvenation of senescent mouse cells. Notably PCL rejuvenates exclusively one single tissue or organ, in contrast to classical

cloning Cloning is the process of producing individual organisms with identical or virtually identical DNA, either by natural or artificial means. In nature, some organisms produce clones through asexual reproduction. In the field of biotechnology, c ...

PCL is therefore unable to reconstitute an entire organism. Furthermore, PCL is feasible in a few hours in opposition to classical cloning or

induced pluripotent stem cell Induced pluripotent stem cells (also known as iPS cells or iPSCs) are a type of pluripotent stem cell that can be generated directly from a somatic cell. The iPSC technology was pioneered by Shinya Yamanaka's lab in Kyoto, Japan, who showed in ...

s (iPS) which all need weeks or months. Classical cloning can rejuvenate old cells but the process demands that the old cells must artificially pass through an embryonic cell stage. Partial cloning affords the advantage that the old cells to be rejuvenated do not have to pass through the embryonic cell stage and are simply made younger. The extension of human lifespan, in terms of useful, quality, years added to life, has been a goal for many since time immemorial. And while a goal whose attainment was thought improbable, or at least achievable only in the far distant future, the discovery that animals can be cloned has brought the goal of rejuvenation much closer. The remarkable discovery that animals can be cloned showed that the nucleus of an old cell can be used as a donor in so-called “nuclear transfer” experiments where an old nucleus is transferred into a recipient egg whose own nuclear material has been removed. The “reconstructed” egg is then prompted to engage development and develops through an embryonic stage that results, once the embryo is implanted into a surrogate mother, into a new born. Thus an old cell can give rise to a newborn, which has a typical lifespan: the age of the donor cell is “wiped clean” and returned to a youthful state. Notably, in classical animal cloning the rejuvenation process involves a return to an embryonic form. Thus the specialized functions of the adult cell are also “wiped clean” and returned to an embryonic cell type. And in classical cloning passage through this embryonic state is a must for the age of the cell to be “wiped clean”. The key notion that exemplifies “partial” cloning from “classical” cloning is the separation of the mechanism(s) that “wipe clean” the specialization of a cell from those that “wipe-clean” the age of the cell. In short, partial cloning aims to retain the specialized functions of a cell and simply make it younger, e.g., a skin cell is rejuvenated without having to pass through the embryonic stage that is a must for rejuvenation via the classical cloning technique (see diagram). In a new laboratory at the Forschungszentrum Borstel our work on partial cloning focuses, inter alia, on the restricted, temporary, incubation of an “old” cell within the egg. In this way only the age of the cell is “wiped clean” and its specialized, differentiated, state is retained. It is simply made younger – rejuvenated - without going through the embryonic state. The measure of Diagram showing the difference between “Classical” and “Partial” cloning: Classical cloning (the route given by the black arrows) can rejuvenate an old cell but requires passage through an embryonic stage. “Partial cloning” (given by the red arrow) rejuvenates old cells without passage through an embryonic stage.“Partial cloning” (given by the red arrow) rejuvenates old cells without passage through an embryonic stage. In a new laboratory at the Forschungszentrum Borstel our work on partial cloning focuses, inter alia, on the restricted, temporary, incubation of an “old” cell within the egg. In this way only the age of the cell is “wiped clean” and its specialized, differentiated, state is retained. It is simply made younger – rejuvenated - without going through the embryonic state. The measure of rejuvenation in our system is, first, the re-acquisition of the ability of an old cell to divide, something that is lost in old cells and, second, the loss of characteristics that are associated with old cells. Should such rejuvenation be achievable the consequences for medicine would be profound. It would avoid the need to artificially pass through an embryonic stage – either by nuclear transfer or by the so-called iPS cells method - to rejuvenate cells. One would simply be able to take aged cells from a patient and then return to the patient their own, histocompatible, rejuvenated heart cells, liver cells etc. In sharp contrast to the cycle of artificial de-differentiation of somatic cells to stem cells and then the artificial re-differentiation of stem cells to the desired differentiated cell type, which is highly inefficient, time-consuming and results in unstable cell types. The process of partial cloning would be efficient and rapid and thus cheap both in terms of materials and manpower. In short, partial cloning has enormous potential to relieve human suffering and disease: it is the most rapid and cheap route to successful regenerative medicine. Partial cloning also avoids the ethical problems associated with “classical” cloning in that it does not result in live born – it mere uses the oocyte briefly as a means to condition and thereby rejuvenate the old cell exclusively.

Method

Application

References

Further reading