Mammalian reproduction is unusually wasteful, due to some interesting processes and tradeoffs.
Now that we have settled the facts that life begins at conception and abortion is murder, a minor question arises. There is a lot of murder going on in early embryogenesis, and who is responsible? Probably god. Roughly two-thirds of embryos that form are aneuploid (have an extra chromosome or lack a chromosome) and die, usually very soon. Those that continue to later stages of pregnancy cause a high rate of miscarriages-about 15% of pregnancies. A recent paper points out that these rates are unusual compared with most eukaryotes. Mammals are virtually alone in exhibiting such high wastefulness, and the author proposes an interesting explanation for it.
First, some perspective on aneupoidy. Germ cells go through a two-stage process of meiosis where their DNA is divided two ways, first by homolog pairs, (that is, the sets inherited from each parent, with some amount of crossing-over that provides random recombination), and second by individual chromosomes. In more primitive organisms (like yeast) this is an efficient, symmetrical, and not-at-all wasteful process. Any loss of genetic material would be abhorrent, as the cells are putting every molecule of their being into the four resulting spores, each of which are viable.
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| A standard diagram of meiosis. Note that the microtubules (yellow) engage in a gradual and competitive process of capturing centromeres of each chromosome to arrive at the final state of regular alignment, which can then be followed by even division of the genetic material and the cell. |
In animals, on the other hand, meiosis of egg cells is asymmetric, yielding one ovum / egg and three polar bodies, which have various roles in some species to assist development, but are ultimately discarded. This asymmetric division sets up a competition between chromosomes to get into the egg, rather than into a polar body. One would think that chromosomes don't have much say in the matter, but actually, cell division is a very delicate process that can be gamed by "strong" centromeres.
Centromeres are the central structures on chromosomes that form attachments to the microtubules forming the mitotic spindle. This attachment process is highly dynamic and even competitive, with microtubules testing out centromere attachment sites, and using tension ultimately as the mark of having a properly oriented chromosome with microtubules from each side of the dividing cell (i.e. each microtubule organizing center) attached to each of the centromeres, holding them steady and in tension at the midline of the cell. Well, in oocytes, this does not happen at the midline, but lopsidedly towards one pole, given that one of the product cells is going to be much larger than the others.
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| In oocytes, cell division is highly asymmetric with a winner-take-all result. This opens the door to a mortal competition among chromosomes to detect which side is which and to get on the winning side. |
One of the mysteries of biology is why the centromere is a highly degenerate, and also a speedily evolving, structure. They are made up of huge regions of monotonously repeated DNA, which have been especially difficult to sequence accurately. Well, this competition to get into the next generation can go some way to explain this structure, and also why it changes rapidly, (on evolutionary time scales), as centromeric repeats expand to capture more microtubules and get into the egg, and other portions of the machinery evolve to dampen this unsociable behavior and keep everyone in line. It is a veritable arms race.
But the funny thing is that it is only mammals that show a particularly wasteful form of this behavior, in the form of frequent aneuploidy. The competition is so brazen that some centromeres force their way into the egg when there is already another copy there, generating at best a syndrome like Down, but for all other chromosomes than #21, certain death. This seems rather self-defeating. Or does it?
The latest paper observes that mammals devote a great deal of care to their offspring, making them different from fish, amphibians, and even birds, which put most of their effort into producing the very large egg, and relatively less (though still significant amounts) into care of infants. This huge investment of resources means that causing a miscarriage or earlier termination is not a total loss at all, for the rudely trisomic extra chromosome. No, it allows resource recovery in the form of another attempt at pregnancy, typically quite soon thereafter, at which point the pushy chromosome gets another chance to form a proper egg. It is a classic case of extortion at the molecular scale.
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