The Effects of Normal Aging on Myelinated Nerve Fibers in Monkey Central Nervous System

The effects of aging on myelinated nerve fibers of the central nervous system are complex. Many myelinated nerve fibers in white matter degenerate and are lost, leading to some disconnections between various parts of the central nervous system. Other myelinated nerve fibers are affected differently, because only their sheaths degenerate, leaving the axons intact. Such axons are remyelinated by a series of internodes that are much shorter than the original ones and are composed of thinner sheaths. Thus the myelin-forming cells of the central nervous system, the oligodendrocytes, remain active during aging. Indeed, not only do these neuroglial cell remyelinate axons, with age they also continue to add lamellae to the myelin sheaths of intact nerve fibers, so that sheaths become thicker. It is presumed that the degeneration of myelin sheaths is due to the degeneration of the parent oligodendrocyte, and that the production of increased numbers of internodes as a consequence of remyelination requires additional oligodendrocytes. Whether there is a turnover of oligodendrocytes during life has not been studied in primates, but it has been established that over the life span of the monkey, there is a substantial increase in the numbers of oligodendrocytes. While the loss of some myelinated nerve fibers leads to some disconnections, the degeneration of other myelin sheaths and the subsequent remyelination of axons by shorter internodes slow down the rate conduction along nerve fibers. These changes affect the integrity and timing in neuronal circuits, and there is evidence that they contribute to cognitive decline.


INTRODUCTION
There are two types of nerve fi bers in the central nervous system, myelinated and unmyelinated ones. The myelinated nerve fi bers are axons of neurons that are ensheathed by internodal lengths of myelin formed by oligodendrocytes. Developmentally, the internodal lengths of myelin are produced at the ends of processes of oligodendrocytes and each internode is generated by a spiral wrapping of a paired sheet of oligodendrocytic plasma membrane. Initially the successive turns of the spiral of paired membrane sheets are separated by cytoplasm, but eventually the cytoplasm is extruded from between the turns. As a result, mature, compact myelin is formed. At the ends of each internodal length of myelin are regions called paranodes, and here the turns of the spiral wraps of myelin membrane successively terminate, the innermost one terminating fi rst (Figure 1). As the turns of myelin terminate the sheath gradually becomes thinner, and eventually end at the nodes of Ranvier, which separate the successive internodal lengths of myelin. At the nodes the axon is bare, but is characterized by a dense undercoating.
An oligodendrocyte forms several internodal lengths of myelin, each one on a different axon, and in general the larger the diameter of the axon, the thicker is its myelin sheath and the longer its internodes and its paranodes (see Figure 1). And since there seems to be some limit to the amount of myelin an individual oligodendrocyte can produce and maintain, oligodendrocytes that myelinate small diameter axons form more internodal lengths of myelin than those fi bers and alterations in the morphology and composition of myelin sheaths, that could account for the decrease in staining intensity. Some of these alterations will be considered in the next sections, which will concentrate primarily on age changes that have been encountered in non-human primates. The correlations that occur between age-related morphological changes in myelinated nerve fi bers and cognitive decline will also be considered.

LOSS OF MYELINATED NERVE FIBERS
Magnetic resonance imaging (MRI) studies of both human (e.g. Albert, 1993;Guttmann et al., 1998) and monkey (Lai et al., 1995;Wisco et al., 2008) brains have shown there is a loss of white matter from the cerebral hemispheres with age. For example, Wisco et al. (2008) calculate that in rhesus monkeys there is a 11.5% loss of white matter from the forebrain with age, in contrast to only a 2% loss of gray matter. However, it should be noted that other studies on humans (e.g. Pfefferbaum et al., 1994;Resnick et al., 2003;Sullivan et al., 2004) and monkeys (Andersen et al., 1999) suggest that loss of volume of the hemispheres is mainly due to a thinning of the cerebral cortex. Nevertheless, there seems to be general agreement that there is some loss of white matter with age and this is supported by stereological studies on cognitively normal human brains. The fi rst of these studies was that of Pakkenberg and Gundersen (1997) who examined brains from humans between 20 and 95 years of age, and using the Cavalieri's principle to determine volume changes, they concluded there is a 28% decrease in the volume of white matter from the cerebral hemispheres. In another study from this same laboratory, Tang et al. (1997) using light and electron microscopy concluded that this loss is due to a 27% overall loss in the lengths of myelinated nerve fi bers from white matter. Later Marner et al. becomes available for examination, the delay in fi xing the tissue usually leaves the structural preservation less than optimal.
Rhesus monkeys live for a maximum of 35 years (Tigges et al., 1988) and the advantage of using them as a model for normal aging is that they are not subject to Alzheimer's disease, and overall, do not lose signifi cant numbers of neurons from their cerebral cortex with age (see Merrill et al., 2000;Morrison and Hof, 1997;Peters et al., 1998), However, Smith et al. (2004 have recently claimed that there may be a focal loss of neurons from cortical area 8A of the prefrontal cortex. None of the neurons in the aging monkey cortex acquire neurofi brillary tangles, and although some senile plaques may be present, particularly in the frontal and primary somatosensory cortices of older monkeys, they are few in number (Heilbroner and Kemper, 1990;Struble et al., 1985). The small numbers of plaques do increase with age in monkeys, but there is no correlation between plaque burden and cognitive decline (Sloane et al., 1997). The other advantage of using monkeys to study normal cognitive decline is that over the entire range of their life span, monkeys can be behaviorally tested to determine their cognitive status, and in our studies their cognitive status is defi ned by a cognitive impairment index (CII). Their brains can then be properly prepared for morphological, physiological or biochemical analyses.
The fi rst hint that there are age-related changes in myelinated nerve fi bers came from the observation that in old humans and monkeys there is a decrease in the intensity of haemotoxylin staining of white matter (e.g., Kemper, 1994;Lintl and Braak, 1983). The underlying reason for this increased myelin staining pallor is still not clear, but it is now know that there are a number of age-related alterations of myelinated nerve fi bers in the primate central nervous system, such as a loss of some myelinated nerve (2003) extended these studies by examining samples that were taken systematically and randomly from the white matter of 36 normal brains of males and females aged between 18 and 93 years. They concluded that though the overall loss of white matter from the human cerebral hemispheres is 23%, the overall decrease in total myelinated nerve fi ber length is even greater, being 45%. A similar loss of myelinated nerve fi bers from the human brain has been reported by Meier-Ruge et al. (1992), who examined the brains of cognitively normal humans and concluded there is a 16% loss of myelinated nerve fi bers from white matter of the precentral gyrus and an 11% loss from the corpus callosum.
Studies of the effects of age on the monkey brain support the contention that there is a loss of myelinated nerve fi bers with age. In each of the white matter tracts we have examined some loss of myelinated nerve fi bers has been found. Over the life span of the monkey the average number of myelinated nerve fi bers lost from the optic nerve (Sandell and Peters, 2001), and from the anterior commissure (Sandell and Peters, 2003) is about 45%, while from the fornix and the splenium of the corpus callosum (unpublished data), the loss is about 25%. In all four structures the correlations between the decreasing numbers of myelinated nerve fi bers and increasing age are signifi cant.
In contrast, there is no measurable loss of myelinated nerve fi bers from the visual cortex (Nielsen and Peters, 2000), but the inability to detect a loss may be due to the relatively sparse numbers of myelinated nerve fi bers present in cortex, because a few myelinated nerve fi bers with degenerating axons have been seen in cortex (Figure 2). Indeed myelinated nerve fi bers with degenerating axons, as indicated in the electron microscope by the presence of dense axoplasm with a loss identifi able organelles, or the presence of empty myelin sheaths (Figure 2), have been encountered in all of the parts of the aging monkey brain that we have examined, suggesting that myelinated nerve fi ber loss is ubiquitous. And based on earlier studies of Wallerian nerve fi ber degeneration, there is little doubt that once an axon degenerates, breakdown and degeneration of its myelin sheath inexorably follows (e.g. Guillery, 1970).
Myelinated nerve fi ber loss from white matter in pathways must result in some disconnection between various parts of the central nervous system. But interestingly, although there are no signifi cant correlations between the extent of myelinated nerve fi ber loss from the splenium of the corpus callosum and the cognitive decline shown by monkeys (Peters and Sethares, 2002), there are correlations between cognitive decline and myelinated nerve fi ber loss from the anterior commissure (Sandell and Peters, 2003) and the fornix (unpublished). In this context, it is interesting that cutting the splenium of the corpus callosum, which is the principal fi ber pathway connecting the occipital cortices, has little effect on cognition (Innocenti, 1986). The anterior commissure, provides the interhemispheric connection between the entire temporal lobe, as well as parts of the orbitofrontal cortex prepiriform cortex and the amygdala (Demeter et al., 1990;Jouandet and Gazzaniga, 1979;Sullivan and Hamilton, 1973a,b), and numerous studies have shown that the anterior commissure provides a pathway whereby visual information can reach the opposite hemisphere and contribute to behavioral responses, such as two-choice discrimination (Doty et al., 1994;Gross et al., 1977;Sobotka and Ringo, 1996). The fornix, on the other hand, carries the main output from the hippocampus, and studies of the effects of lesioning the fornix in both monkeys (Fletcher et al., 2006;Gaffan et al., 2001;Owen and Butler, 1981;Wilson et al., 2007) and humans (e.g. D'Esposito et al., 1995;Gaffan et al., 1991) have revealed the role of the fornix in memory and have described amnesia as a major consequence of making such lesions.
It might be assumed that since myelinated nerve fi bers are lost from white matter with age, that there must be a concomitant loss of the neurons from which the nerve fi bers arise. For the optic nerve, this may be the case, since retinal ganglion cells are subject to damage from ocular changes and systemic disease that occurs frequently in the elderly (Garner et al., 1994). But for the other central nervous system pathways, in which the myelinated nerve fi bers arise from cortical neurons, a different reason has to be sought, because, as stated above, recent studies have shown that in normal aging few neurons are lost from the cerebral cortices of either monkeys or humans (e.g., Hof et al., 2000;Merrill et al., 2000;Morrison and Hof, 1997;Pakkenberg and Gundersen, 1997;Peters et al., 1998), andFreeman et al. (2008) have recently shown that in normally aging humans cortical neuron numbers are preserved even when there is cortical atrophy. To account for the age-related loss of myelinated nerve fi bers from white matter, we have suggested that only the portion of the axonal plexus of a pyramidal cell that enters the white matter, degenerates by a dying back process, leaving the more extensive local axonal plexus in the cortex intact (Peters and Rosene, 2003). This scenario would account both for the loss of some myelinated nerve fi bers from white matter and for the failure to detect myelinated nerve fi ber loss from the cerebral cortex itself.

DEGENERATIVE CHANGES IN MYELIN SHEATHS
Obviously, in normal aging some myelin sheaths degenerate as a consequence of their axons degenerating, but in other cases myelin sheaths degenerate even though the axon is intact. In the latter category there are two kinds of myelin sheath alterations. The most common age-related degenerative alteration is an accumulation of dark cytoplasm in pockets that are produced by a splitting of the major dense line (e.g. Peters et al., 1994;Peters and Sethares, 2002;Peters et al., 2000;Sandell and Peters, 2003). Examples of what will be referred to as dense sheaths are shown in Figure 3. The location of the dense cytoplasm in splits of the major dense line implies that the cytoplasm must be derived from the parent oligodendrocyte, because the major dense line of the myelin sheath is produced by apposition of the cytoplasmic faces of the plasma membrane of the oligodendrocyte forming the myelin sheath. The amount of dense cytoplasm can vary from a small amount contained in a local split of the sheath to an accumulation that is extensive, causing the sheath to bulge out into the surrounding intercellular space. Longitudinal sections of affected sheaths show that the accumulations of dense cytoplasm are localized, although there may be several such loci along an internodal length of myelin. Proof of the fact that the accumulation of dense cytoplasm in normal aging is a degenerative change comes from studies of Curprizone toxicity, which leads to oligodendrocyte death, resulting in the formation of dense cytoplasm in the cytoplasmic process on the inner face of the myelin sheath (Ludwin, 1978). A similar dense cytoplasm also occurs in the sheaths of mice with a myelin-associated glycoprotein defi ciency (e.g. Lassmann et al., 1997).
Another, but less common myelin alteration associated with aging is the formation of myelin balloons (e.g. Feldman and Peters, 1998;Peters and Sethares, 2003). These balloons can be as large as 10 µm in diameter, so that even by light microscopy the larger balloons they are visible as holes in the neuropil of the aging cortex. Electron microscopic analyses show that these holes are really localized fl uid-fi lled cavities that are accommodated by splits in the intraperiod line of the affected sheaths, and since the intraperiod line is produced by apposition of the outer faces of the cytoplasmic membrane of the oligodendrocyte, the fl uid-fi lled sacs are potentially in contact with the extracellular space. In larger balloons, the axon of the nerve fi ber is pushed to one side of the sheath, suggesting that the fl uid in the sac must be exerting some pressure. But despite this, the sheath is of the same thickness all around the balloon, and there is no obvious change in the periodicity of the myelin lamellae. Consequently it does not appear that the myelin sheath is elastic, and so the formation of a balloon must entail the production of excess myelin by the parent oligodendrocyte. It should be emphasized that dense sheaths and balloons are not entirely separate entities, since it is not uncommon for a balloon to have some dense cytoplasm at its base, or for a sheath with a balloon to have some dense cytoplasm between its lamellae.
Again, there is evidence that the formation of balloons is a degenerative process, since myelin balloons can be produced by Cuprizone (Ludwin, 1978) and tetraethyl tin (Malamud and Hirano, 1973) toxicity, and by chronic copper poisoning (Hull and Blakemore, 1974). Balloons can also occur in early phases of Wallerian degeneration (Franson and Ronnevi, 1989), and in severe diabetes (Tamura and Parry, 1994).
When the percentage of myelinated nerve fi bers showing either the presence of dense cytoplasm or of balloons is examined, it is found that the frequency of such profi les increases signifi cantly with age (e.g. Feldman and Peters, 1998). More importantly there are signifi cant correlations between cognitive declines and the frequency of profi les of degenerating sheaths in cortical area 46 (Peters and Sethares, 2002), splenium of the corpus callosum (Peters and Sethares, 2002), anterior commissure (Sandell and Peters, 2003), and fornix (unpublished data). An exception is primary visual cortex, in which there is no correlation between cognitive decline and myelin sheath degeneration . This may be because primary visual cortex has little role in cognition. It is presumed that the correlations between myelin degeneration and cognition are due to the degenerating slowing down conduction velocity, and thus affecting the timing in neuronal circuits. Duce et al. (2007) have identifi ed a number of genes that might produce cytotoxicity in white matter. These genes range from ones that can affect life span, to ones that can affect the reorganization of glial cytoskeleton, others that can produce oxidative and proteolytic injury, and yet others that are cell cycle inhibitors. But these authors focus particular attention on a gene called Klotho, a multifunctional gene that is known to defend against oxidative stress, and suggest that with a decrease in the activity of Klotho there is a loss of this protection, which may result in the death of oligodendrocytes.

THE CONTINUED FORMATION OF MYELIN
There are other age-related alterations in myelin sheaths, which indicate that myelin continues to form with age. The fi rst is an increase in the overall thickness of normal myelin sheaths with age. Thus, in the primary visual cortex of the monkey the mean number of lamellae in sheaths of myelinated nerve fi bers in layer 4Cβ of young monkeys is 5.6, while in old monkeys it is 7.0 . However, the increase in thickness of sheaths is not uniform, because the mean increase in the numbers of lamellae is largely because thick sheaths, with more than 10 lamellae, become more common in old monkeys. This increase in the numbers of lamellae on nerve fi bers with thicker myelin sheaths often affects their paranodes, so that whereas longitudinal sections of young nerve fi bers show the paranodal pockets of cytoplasm to terminate is a regular sequence and to be all in contact with the underlying axolemma (see Figure 1), in nerve fi bers of old monkeys with thicker sheaths the paranodes can be disarrayed. They can be piled up on one another, so that only some of the paranodal loops are in contact with the axolemma (Hinman et al., 2006). A similar situation has been reported in the myelinated nerve fi bers of old rats (Sugiyama et al., 2002), and it seems likely that such disruption of the paranodal region could affect conduction velocity. As yet, not determination seems to have been made about whether myelin sheaths in white matter also become thicker with age.
Another change that is considered to indicate the continued formation of myelin is the formation of sheaths that contain redundant myelin, so that the sheaths are too large for their enclosed axons. When such sheaths are cross-sectioned and examined by electron microscopy the axon is seen to be located at one end of an excessively large sheath that loops off into the surrounding neuropil. Such sheaths were fi rst described by Rosenbluth (1966) in the cerebellum of the toad. Sturrock (1976) described such sheaths in anterior commissures of old mice, and later Cullen and Webster (1979) found them to be common in the optic nerves of metamorphosing toads. During metamorphosis the optic nerves become shorter, and the myelin sheaths undergo extensive remodeling, producing redundant sheaths that disappear later in development. These events led Cullen and Webster to suggest that the overproduction of myelin is to allow the sheaths to enlarge so that they can accommodate subsequent increases in the diameters of the enclosed axons. However, the role of redundant sheaths in the aging process is not yet evident, although axons in these sheaths generally have small diameters.

REMYELINATION
When the frequencies of various kinds of profi les of myelinated nerve fi bers are quantifi ed in the vertical bundles of nerve fi bers in the cerebral cortex it becomes evident that the frequency of profi les of paranodes increases with age (Peters and Sethares, 2003). As pointed out earlier, for the present purposes the paranodes are defi ned as those regions at the ends of internodes where the spiraled myelin lamellae gradually terminate as the sheath approaches a node of Ranvier. As the myelin lamellae terminate, the major dense line opens up to accommodate a spiral of cytoplasm, which in longitudinal sections through paranodes appears as a series of pockets of cytoplasm on each side of the axon (see Figure 1). Where the plasma membrane on the inner faces of these pockets meet the axolemma, the two membranes, become very close to each other and form a junctional complex. This membrane apposition makes it quite easy to identify profi les of myelinated nerve fi bers sectioned through paranodes (Figure 3), and it turns out there is a 57% increase in the frequency of paranodal profi les in the aging visual cortex, a 90% increase in area 46 of prefrontal cortex (Peters and Sethares, 2003), and a 60% increase in the anterior commissure (Sandell and Peters, 2003).
There could be two reasons for these age-related increases in paranodal profi les. One is an increase in the lengths of the paranodes with age. The second is an overall increase in the numbers of paranodes. Paranodes do become slightly longer as the numbers of lamellae in myelin sheaths increase with age, but not enough to account for the 60% or more increase in the frequency of paranodal profi les. Consequently, the increase in frequency has to be due to an increase in the overall numbers of internodal lengths of myelin. This would occur if remyelination were taking place, such that some of the original internodal lengths of myelin degenerate and are replaced by shorter internodes. The accepted hallmarks of remyelination are the presence of short internodes and of sheaths that are inappropriately thin for the size of the enclosed axons (e.g. Brück et al., 2003;Hirano, 1989;Kreutzeberg et al., 1997;Ludwin, 1995;Prineas and McDonald, 1997). Such internodes have been found in the aging central nervous system. Internodes of myelin, as short as 3-8 µm, are present in old monkeys, as well as sheaths that are inappropriately thin for the size of the enclosed axon (see Peters and Sethares, 2003).
We have not been able to identify demyelinated nerve fi bers in the monkey brain, but this should not be a surprise, since such demyelinated nerve fi bers would be expected to resemble unmyelinated nerve fi bers. However, in support of the fact that demyelination is taking place, we have seen fragments of degenerating myelin within the cytoplasm of both microglia, and more commonly within astrocytes in the brains of aging monkeys. Also some of the amorphous phagocytosed material within the cytoplasm of astrocytes in the cerebral cortex of old monkeys labels for antibodies to myelin basic protein (Peters and Sethares, 2003).
A recent article on the remyelination of rubrospinal nerve fi bers that remyelinate after a contusion lesion of the spinal cords of mice serves to shed some light on what is happening during aging. Lasiene et al. (2008) have shown that remyelinated nerve fi bers in the rubrospinal tract of mice have much shorter internodal lengths than in control mice, and that these remyelinated axons conduct at a lower rate than the controls. There is also evidence that there are reductions in conduction velocity in the nerve fi bers of aging cats (Morales et al., 1987;Xi et al., 1999). A reduction in conduction velocity also occurs in demyelinating diseases (e.g. Felts et al., 1997;Waxman et al., 1995).
Consequently, it can be assumed that remyelinated nerve fi bers with shorter internodes in the aging monkey also have a slower conduction rate than the nerve fi bers that remain unaffected by age, and that this would affect the timing in neuronal circuits (e.g. see Wang et al., 2005). However, when correlations between the frequency of occurrence of profi les of paranodes and the overall cognitive status of individual monkeys, as measured by the Cognitive Impairment Index, CII, are examined, there is no signifi cant correlation between the two measures, for visual cortex and anterior commissure, but there is a correlation for area 46 of prefrontal cortex (p < 0.01; Peters and Sethares, 2002). The reason for this correlation between CII and paranodal frequency may have to do with the unique role of prefrontal cortex in cognition.

EFFECTS OF AGE ON OLIGODENDROCYTES
In monkey cerebral cortex stained with Perl's reaction for ferric iron the processes of some oligodendrocytes in old monkeys show swellings along their lengths (Figure 4; insert), and when these swellings FIGURE 4 | Electron micrograph of an oligodendrocyte in layer 6 of area 17 of a 35-year-old rhesus monkey. Three processes, p1-p3, extend from the cell body. One of the processes, p1, has a swelling that contains dense inclusions, which are similar to the dense inclusions in the cell body. Scale bar = 1 micron.
The insert shows a light microscopic image of an oligodendrocyte stained with Perl's reaction for iron compounds. Note the large swelling (arrow) on one of the processes. It is similar to the one seen on process p1 in the accompanying electron micrograph. Area 46 of a 28-year-old monkey. Scale bar = 10 microns.

Peters
Myelinated nerve fi bers and aging are examined in the electron microscope it is seen that they contain dense inclusions (Figure 4). Similar dense inclusions also occur in the perikarya of old oligodendrocytes (Peters, 1996;Peters and Sethares, 2004;Peters et al., 1991), and since the dense material is not membrane bound, it is unlikely to be produced by phagocytosis. Similar swellings along oligodendrocyte processes have been reported in twitcher mice, which are a model for globoid leukodystrophy, and Levine and Torres (1992) suggest that the material in the swellings comes from components of myelin sheaths that are being renewed. Most probably the material is produced by degeneration of some components of the myelin sheaths that belong to the oligodendrocytes, and it is tempting to suggest that the material is related to the dense cytoplasm that accumulates between the lamellae of some sheaths in old monkeys. It is also common in old monkeys to fi nd oligodendrocytes in pairs, rows and groups, suggesting that oligodendrocytes may be proliferating with age (Peters and Sethares, 2004;Peters et al., 1991), and when comparisons are made between the numbers of oligodendrocytes in young and old primary visual cortices it is evident that there is an increase in the numbers of oligodendrocytes with age (Peters et al., 1991). Thus in layer 4Cβ for example, in which oligodendrocytes account for about 55% of the total population of neuroglial cells, there is a 50% increase in the numbers of oligodendrocytes with age (Peters and Sethares, 2004). In a more recent study an assessment was made of the effects of age on the populations of neuroglial cells throughout the depth of monkey primary visual cortex . It was seen that the numbers of oligodendroglial cells in the various layers essentially refl ects the frequency of myelinated nerve fi bers within them, the greatest numbers of oligodendrocytes being in the deeper layers. Again, with age the numbers of oligodendrocytes in all layers was found to increase by about 50%. In contrast, there are no changes in the frequency of either astrocytes or microglial cells with age. There is also an increase in the frequency of oligodendrocytes in monkey optic nerve with age (Sandell and Peters, 2002), as well as in the fornix (unpublished data), but not in the anterior commissure (Sandell and Peters, 2003). The reason for this difference is not yet apparent.
What is the origin of the increased numbers of oligodendrocytes that are generated, and why are they necessary? The formation of groups and rows of oligodendrocytes during aging could be taken to suggest that oligodendrocytes are dividing, but the prevailing view is that mature oligodendrocytes do not divide (see Keirstead and Blakemore, 1997;Ludwin, 1995;Norton, 1996), and in a study of the generation of new cells in the adult dentate gyrus of the hippocampus in old monkeys using BrdU labeling no labeled oligodendrocytes were found (Ngwenya et al., 2008). It is more likely that new oligodendrocytes originate from the oligodendroglial precursor cells which express NG2 chondroitin sulfate, These cells are scattered throughout the central nervous system, and in adult rodents they account for about 5% of all neuroglial cells (e.g. Levine et al., 2001).  (2008). Preservation of neuronal number despite agerelated cortical brain atrophy in Studies such as that by Cerghet et al. (2006) have shown that there is a turnover of oligodendroglial cells in the adult mouse, such that some oligodendrocytes undergo apoptosis, and die, while new oligodendrocytes are being generated. And interestingly, Cerghet et al. (2006) found the turnover of oligodendrocytes in the corpus callosum to be greater in female mice than in males, indicating that the lifespan of oligodendrocytes is shorter in females than in males. Moreover, Rivers et al. (2008) have recently shown that in adult mice many of the newly generated oligodendrocytes that arise from the oligodendrocytic precursor cells during adult hood are involved in myelination. They calculate that about 20% of all oligodendrocytes in the adult corpus callosum are generated during adulthood and that many of these cells form myelin. In contrast, the same group calculates that only about 5% of the adult-born oligodendrocytes in the cerebral cortex appear to be involved in the elaboration of myelin sheaths, but Rivers et al. (2008) were not able to determine the function of the other adult generated oligodendrocytes present in cortex.
Unfortunately there is no information about the rate of turnover of oligodendrocytes in the adult monkey, but there is no reason to doubt that it is basically different from in rodents.

A SYNTHESIS
It is proposed that the following scenario can explain the available data on the effects of age on myelinated nerve fi bers in the central nervous system of the monkey. During aging some neurons lose their long projecting myelinated axons that enter white matter, while retaining their local plexuses so that the parent neuron does not die. The consequence of this is that, as has been demonstrated, some myelinated nerve fi bers are lost from white matter, even though there is no signifi cant loss of neurons from the cerebral cortex. For other neurons the effects of aging are less severe (see Figure 5), since their axons remains intact, even though some of the internodal lengths of myelin that ensheath them degenerate ( Figure 5B). The process of demyelination probably begins as an oligodendrocyte shows stress and starts to accumulate dense inclusions in swellings of its processes and in its perikaryon, as well as in spaces between the lamellae of the myelin sheaths for which the oligodendrocyte is responsible. Ultimately the oligodendrocyte dies, which results in the degeneration and loss of the internodal lengths of myelin belonging to that oligodendrocyte ( Figure 5C). Oligodendrocyte precursor cells are then activated and generate new oligodendrocytes that repair the damage by remyelinating the bare lengths of axons. In the process of remyelination, several new oligodendrocytes are involved in the replacement of the original internode of myelin. These oligodendrocytes produce shorter internodal lengths than the original one, and the new sheaths are thinner ( Figure 5D). Thus, when profi les of sectioned myelin sheaths in older monkeys are examined, it is found there is an increase in the number of profi les of paranodes, and this is accompanied by an increase in the total number of oligodendrocytes. This breakdown of myelin sheaths, together with the formation of shorter internodal lengths of myelin and the consequent increase in the number of nodes of Ranvier, would result in a slowing down of the rate of conduction along affected myelinated nerve fi bers. Consequently the timing in neuronal circuits would be affected and contribute to cognitive impairment that occurs with increasing age.