Problems in the standardization of Factor VIII assays

An international system of unitage, based on the World Health Organization International Standard, exists for the measurement of factor VIII clotting activity (VIII: C). In recent years, systematic discrepancies between assay results in different laboratories have brought to light two major problems in VIII: C standardization. Firstly, large discrepancies can arise between laboratories even when the same assay method is used. These are due mainly to differences in reagents. Secondly, when assaying plasmas against concentrates, there is, on average, a 20% discrepancy between one-stage and two-stage potency estimates. At least half this discrepancy appears to be attributable to the step of aluminium hydroxide adsorption, which is routine in the two-stage assay, but not used in the one-stage assay. The combined implication of these discrepancies, namely that the result of an VIII: C assay depends both on assay method and on reagents, reveals certain limitations in the present system of standardization.

The nature and causes of ageing

Ageing is a process where the end result is obvious but the mechanism remains obstinately obscure. The phenomenology of senescence is rich in the abundance of model systems that it offers for the experimental study of ageing. The field is also rich in the theories to account for ageing in terms of specific changes noted or postulated to occur as organisms grow older. Since neither models nor theories are scarce, the slowness of progress to date may therefore be due at least partly to inadequate cross-referencing between the two. Both in the choice of a model organism or cell system and in the selection of a specific mechanism to study, it is important to have in mind the nature and role of ageing at the organism level. Recent evolutionary insights into ageing suggest that senescence occurs because through natural selection a strategy is favoured in which organisms invest fewer resources in the maintenance and repair of somatic cells and tissues than are necessary for indefinite survival of the individual. This 'disposable soma' theory provides a broad predictive framework within which to assess the relevance of models with which to investigate specific mechanisms of ageing.

A stochastic model of cell replicative senescence based on telomere shortening, oxidative stress, and somatic mutations in nuclear and mitochondrial DNA

Human diploid fibroblast cells can divide for only a limited number of times in vitro, a phenomenon known as replicative senescence or the Hayflick limit. Variability in doubling potential is observed within a clone of cells, and between two sister cells arising from a single mitotic division. This strongly suggests that the process by which cells become senescent is intrinsically stochastic. Among the various biochemical mechanisms that have been proposed to explain replicative senescence, particular interest has been focussed on the role of telomere reduction. In the absence of telomerase--an enzyme switched off in normal diploid fibro-blasts-cells lose telomeric DNA at each cell division. According to the telomere hypothesis of cell senescence, cells eventually reach a critically short telomere length and cell cycle arrest follows. In support of this concept, forced expression of telomerase in normal fibroblasts appears to prevent cell senescence. Nevertheless, the telomere hypothesis in its basic form has some difficulty in explaining the marked stochastic variations seen in the replicative lifespans of individual cells within a culture, and there is strong empirical and theoretical support for the concept that other kinds of damage may contribute to cellular ageing. We describe a stochastic network model of cell senescence in which a primary role is played by telomere reduction but in which other mechanisms (oxidative stress linked particularly to mitochondrial damage, and nuclear somatic mutations) also contribute. The model gives simulation results that are in good agreement with published data on intra-clonal variability in cell doubling potential and permits an analysis of how the various elements of the stochastic network interact. Such integrative models may aid in developing new experimental approaches aimed at unravelling the intrinsic complexity of the mechanisms contributing to human cell ageing.

Ageing of murine small intestinal stem cells

Most organs of the body comprise populations of cells that are committed to specialized functions and that are renewed from small numbers of uncommitted progenitor or 'stem' cells. Stem cells are of central importance in the study of ageing because any senescent decline in the number or functional competence of stem cells will impair the capacity for renewal and turnover of committed cells, with potentially serious consequences for tissue homeostasis. The intestinal epithelium represents an excellent model system for the study of stem cells. Its spatial and hierarchical organisation allows the study of the function or characteristic of a given cell according to its position within the crypt. Hence, the stem cells which are located at the 4th-5th cell position from the bottom can be studied together with their daughter cells, as they divide and differentiate while migrating along the crypt-villus axis. The ability of the stem cells to undergo apoptosis and the capacity to regenerate the epithelium following injury were investigated in mice of different ages. Stem cells from older animals showed an increased apoptotic response following exposure to low doses of ionising radiation. The regenerative capacity was estimated by measuring the crypt survival levels and the growth rate of surviving crypts after high doses of irradiation. Surviving crypts in the older mice, suggesting an impairment in the damage recognition/response mechanisms, were both fewer and smaller than in young mice. The growth rate of surviving crypts was determined by measuring the crypt area and the number of cells/crypt at various times after 14 Gy irradiation. There was a growth delay of between half and one day in the older mice, and they subsequently grew more slowly. The number of cells susceptible to regenerate a crypt was also estimated. Surprisingly, they appear to be more numerous in the older mice. These studies indicate important age-related alterations in the capacity of the stem cells to regenerate the crypts after radiation-induced damage. The molecular bases of these changes are currently being investigated. Preliminary data showed alteration in the level of p53 and p21 expression, suggesting an age-related defect in the capacity to recognize damage and initiate apoptosis or repair.

Stress, DNA damage and ageing -- an integrative approach

Ageing is highly complex, involving multiple mechanisms at different levels. Nevertheless, recent evidence suggests that several of the most important mechanisms are linked via endogenous stress-induced DNA damage caused by reactive oxygen species (ROS). Understanding how such damage contributes to age-related changes requires that we explain how these different mechanisms relate to each other and potentially interact. In this article, we review the contributions of stress-induced damage to cellular DNA through (i) the role of damage to nuclear DNA and its repair mediated via the actions of poly(ADP-ribose) polymerase-1, (ii) the role of damage to telomeric DNA and its contribution to telomere-driven cell senescence, and (iii) the role of damage to and the accumulation of mutations in mitochondrial DNA. We describe how an integrative approach to studying these mechanisms, coupled with computational modelling, may be of considerable importance in resolving some of the complexity of cellular ageing.

If you would live long, choose your parents well

Human longevity appears to have a modest but significant heritable component. A recent study in Iceland has added to this evidence by making a unique assessment based on records for an entire population. Although the evidence for inheritance of human lifespans appears robust, there remains considerable uncertainty about the extent of the genetic versus the nongenetic contribution and about the importance of gene-environment interactions. Sex-specific patterns of transmission of lifespan between parents and offspring might provide clues to the basis of lifespan heritability, but the reported patterns are neither conclusive nor consistent.

Sex and ageing

Sex and ageing are often linked, particularly in the context of the evolutionary theories of ageing, which suggest that senescence may be the price for investing in offspring at the expense of somatic maintenance and repair. Considerable evidence supports this concept although, strictly, it is not sex per se but the existence of the soma/germ-line distinction that appears to hold the key. Other aspects of the sex-ageing axis seeing exciting new developments are the evolution of the human life history, particularly with respect to menopause, and the molecular mechanisms that sustain the immortality of the germ-line in contrast to the cumulative damage that appears to underlie the ageing of somatic cells.

Evolution of the human menopause

Menopause is an evolutionary puzzle since an early end to reproduction seems contrary to maximising Darwinian fitness. Several theories have been proposed to explain why menopause might have evolved, all based on unusual aspects of the human life history. One theory is that menopause follows from the extreme altriciality of human babies, coupled with the difficulty in giving birth due to the large neonatal brain size and the growing risk of child-bearing at older ages. There may be little advantage for an older mother in running the increased risk of a further pregnancy when existing offspring depend critically on her survival. An alternative theory is that within kin groups menopause enhances fitness by producing post-reproductive grandmothers who can assist their adult daughters. Such theories need careful quantitative assessment to see whether the fitness benefits are sufficient to outweigh the costs, particularly in circumstances of relatively high background mortality typical of ancestral environments. We show that individual theories fail this test, but that a combined model incorporating both hypotheses can explain why menopause may have evolved.

Why do we age?

The evolutionary theory of ageing explains why ageing occurs, giving valuable insight into the mechanisms underlying the complex cellular and molecular changes that contribute to senescence. Such understanding also helps to clarify how the genome shapes the ageing process, thereby aiding the study of the genetic factors that influence longevity and age-associated diseases.

Calorie restriction and aging: a life-history analysis

The disposable soma theory suggests that aging occurs because natural selection favors a strategy in which fewer resources are invested in somatic maintenance than are necessary for indefinite survival. However, laboratory rodents on calorie-restricted diets have extended life spans and retarded aging. One hypothesis is that this is an adaptive response involving a shift of resources during short periods of famine away from reproduction and toward increased somatic maintenance. The potential benefit is that the animal gains an increased chance of survival with a reduced intrinsic rate of senescence, thereby permitting reproductive value to be preserved for when the famine is over. We describe a mathematical life-history model of dynamic resource allocation that tests this idea. Senescence is modeled as a change in state that depends on the resources allocated to maintenance. Individuals are assumed to allocate the available resources to maximize the total number of descendants. The model shows that the evolutionary hypothesis is plausible and identifies two factors, both likely to exist, that favor this conclusion. These factors are that survival of juveniles is reduced during periods of famine and that the organism needs to pay an energetic "overhead" before any litter of offspring can be produced. If neither of these conditions holds, there is no evolutionary advantage to be gained from switching extra resources to maintenance. The model provides a basis to evaluate whether the life-extending effects of calorie-restriction might apply in other species, including humans.

Molecular gerontology. Bridging the simple and the complex

It is clear, both empirically and theoretically, that the mechanisms of aging are multiple and complex. Nevertheless, single gene mutations and simple interventions such as calorie restriction have broad effects on the senescent phenotype. The major challenge is to unite highly reductionist analysis of molecular components with integrative model systems that can "put it all together." Two themes are developed. In the first, biochemical models are described that show how the network concept of cellular aging can be used to integrate multiple biochemical mechanisms that contribute to cellular instability. In the second theme, the role of intrinsic developmental chance is examined as a major factor contributing, in addition to genes and environment, to the divergence of the senescent phenotype. The implications of these themes for research strategies in molecular gerontology are discussed.

Accumulation of defective mitochondria through delayed degradation of damaged organelles and its possible role in the ageing of post-mitotic and dividing cells

The mitochondrial theory of ageing proposes that an accumulation of defective mitochondria is a major contributor to the cellular deterioration that underlies the ageing process. The plausibility of the mitochondrial theory depends critically upon the population dynamics of intact and mutant mitochondria in different cell types. Earlier work suggested that mutant mitochondria might have a replication advantage but failed to account for the fact that mutants accumulate faster in post-mitotic than in dividing cells. We describe a new mathematical model that allows for damaged mitochondria to replicate more slowly, which accommodates experimental evidence of impaired energy generation and a reduced proton gradient in defective mitochondria. However, this is compensated for by a slower degradation rate of damaged mitochondria than intact ones, as suggested by de Grey (1997), which gives damaged mitochondria a selective advantage and leads to a clonal expansion of damaged mitochondria. This theoretical result is important because it agrees with evidence that, during ageing, single muscle fibres are taken over by one or only a few types of mtDNA mutants. The model also shows that cell division can rejuvenate and stabilize the mitochondrial population, consistent with data that post-mitotic tissues accumulate mitochondrial damage faster than mitotically active tissues.

Positive correlation between mammalian life span and cellular resistance to stress

Identifying the mechanisms determining species-specific life spans is a central challenge in understanding the biology of aging. Cellular stresses produce damage, that may accumulate and cause aging. Evolution theory predicts that long-lived species secure their longevity through investment in a more durable soma, including enhanced cellular resistance to stress. To investigate whether cells from long-lived species have better mechanisms to cope with oxidative and non-oxidative stress, we compared cellular resistance of primary skin fibroblasts from eight mammalian species with a range of life spans. Cell survival was measured by the thymidine incorporation assay following stresses induced by paraquat, hydrogen peroxide, tert-butyl hydroperoxide, sodium arsenite and alkaline pH (sodium hydroxide). Significant positive correlations between cell LD90 and maximum life span were found for all these stresses. Similar results were obtained when cell survival was measured by the MTT assay, and when lymphocytes from different species were compared. Cellular resistance to a variety of oxidative and non-oxidative stresses was positively correlated with mammalian longevity. Our results support the concept that the gene network regulating the cellular response to stress is functionally important in aging and longevity.

Human longevity at the cost of reproductive success

The disposable soma theory on the evolution of ageing states that longevity requires investments in somatic maintenance that reduce the resources available for reproduction. Experiments in Drosophila melanogaster indicate that trade-offs of this kind exist in non-human species. We have determined the interrelationship between longevity and reproductive success in Homo sapiens using a historical data set from the British aristocracy. The number of progeny was small when women died at an early age, increased with the age of death, reaching a plateau through the sixth, seventh and eighth decades of life, but decreased again in women who died at an age of 80 years or over. Age at first childbirth was lowest in women who died early and highest for women who died at the oldest ages. When account was taken only of women who had reached menopause, who were aged 60 years and over, female longevity was negatively correlated with number of progeny and positively correlated with age at first childbirth. The findings show that human life histories involve a trade-off between longevity and reproduction.

Ovarian ageing and the general biology of senescence

Ovarian ageing is not only of major importance in its own right but is also of interest for its relationship with the general biology of senescence. A key feature of ageing is the distinction in higher animals between the immortality of the germ-line and the mortality of somatic cells and tissues. The ovary contains the female germ cells, and it is through these cells that the female contribution to germ-line immortality is effected. It is abundantly clear that individual oocytes can and do age and that the ageing of the ovary plays a major role in initiating or accelerating a series of other senescent changes. To understand how ovarian ageing fits within the general biology of senescence, it is necessary to explain why ageing occurs at all, to examine the likely mechanisms of general ageing, and to ask whether there is anything special about ovarian ageing and its relationship with the human menopause. Research on ovarian ageing interacts with the our emerging understanding of the general biology of senescence at many levels, ranging from the evolution of the human life history to the biochemical and cellular mechanisms of ageing and longevity.

Altered stem cell regeneration in irradiated intestinal crypts of senescent mice

Ageing is associated with a progressive deterioration in the functions of many organs within the body. In tissue with high cell turnover, the maintenance of the stem cells is of particular importance. Any accumulation of damage in stem cells may affect their function and hence threaten the homeostasis and regenerative capacity of the tissue. The small intestine represents a good model for the study of stem cells because of its spatial and hierarchical organisation. We have examined the effect of age on stem cell regenerative capacity after irradiation, using the microcolony assay. Crypt survival levels, the growth rate of surviving crypts, and the number of cells able to repopulate a crypt have been investigated by irradiating groups of 6–7 month old and 28–30 month old ICRFa male mice. After high doses of irradiation, the surviving crypts in old mice were both smaller and fewer in number than in young mice. The growth rate of surviving crypts was determined by measuring the crypt area and the number of cells/crypt at various times after 14 Gy irradiation. There was a growth delay of between about one half and one day in the older mice. Surprisingly, the number of clonogenic cells per crypt was estimated to be greater in the older mice. These studies indicate important age-related alterations in the capacity to regenerate the crypts after radiation damage.

Age changes in stem cells of murine small intestinal crypts

Cell senescence is seen in many types of differentiated cells but age changes in stem cells have not previously been clearly demonstrated. Changes in stem cells may be of great importance for the ageing process, because any decline with age in the numbers and functional integrity of stem cells can lead to progressive deterioration of function and of proliferative homeostasis in tissues. Stem cells of the murine small intestine provide an excellent model system because these cells occupy a well-defined position near the base of the crypts of Lieberkühn. We examined mice aged between 5 and 32 months and found age-related alterations in the histology of the small intestine and in the apoptotic response of stem cells to low-dose irradiation. Apoptosis in the crypts is concentrated around the stem cell position and can be markedly elevated by exposure to radiation or cytotoxic agents, suggesting that "suicide" of damaged stem cells may be an important system for long-term tissue maintenance. Animals aged 5, 15, 18, and 29 months were exposed to either 1 or 8 Gy gamma irradiation. A twofold increase in the level of apoptosis was seen following 1 Gy gamma irradiation in the 29-month-old animals, compared to the young and middle-age groups. After 8 Gy irradiation the level of apoptosis in all age groups was high and the age effect less pronounced. The data suggest that stem cells do undergo some functional alteration with age.

The origins of human ageing

The origins of human ageing are to be found in the origins and evolution of senescence as a general feature in the life histories of higher animals. Ageing is an intriguing problem in evolutionary biology because a trait that limits the duration of life, including the fertile period, has a negative impact on Darwinian fitness. Current theory suggests that senescence occurs because the force of natural selection declines with age and because longevity is only acquired at some metabolic cost. In effect, organisms may trade late survival for enhanced reproductive investments in earlier life. The comparative study of ageing supports the general evolutionary theory and reveals that human senescence, while broadly similar to senescence in other mammalian species, has distinct features, such as menopause, that may derive from the interplay of biological and social evolution.

What is the relationship between osteoarthritis and ageing?

The relationship between osteoarthritis and ageing raises important questions about what exactly defines 'normal' ageing and whether the pathogenesis of osteoarthritis shares common pathways with other age-associated dysfunctions, or whether osteoarthritis is a time-dependent disorder distinct from normal ageing with a separate causative mechanism at work. Theories of ageing now emphasize the stochastic nature of the ageing process, that is the role played by accumulation of essentially random cell and tissue damage, such as somatic mutations, oxidative damage and the formation of aberrant proteins. The role of genetic factors in determining longevity and predisposition to age-associated diseases is probably in programming the efficiency of somatic maintenance functions and in influencing the development of a durable soma. Gene-environment interactions, for example through lifestyle, can also be important. Many of the risk factors and mechanisms that are thought to contribute to osteoarthritis can be accommodated within this framework.

Network theory of aging

Evolution theory indicates that investment in mechanisms of somatic maintenance and repair is likely to be limited, suggesting that aging may result from the accumulation of unrepaired somatic defects. An important corollary of this hypothesis is that multiple mechanisms of aging operate in parallel. We describe a recently developed "network theory of aging" that integrates the contributions of defective mitochondria, aberrant proteins, and free radicals in the aging process and that includes the protective effects of antioxidant enzymes and proteolytic scavengers. Possibilities for further extension of the theory and its role in prediction and simulation of experimental results are discussed.

Human senescence

Human life expectancy has increased dramatically through improvements in public health, housing, nutrition and general living standards. Lifespan is now limited chiefly by intrinsic senescence and its associated frailty and diseases. Understanding the biological basis of the ageing process is a major scientific challenge that will require integration of molecular, cellular, genetic and physiological approaches. This article reviews progress that has been made to date, particularly with regard to the genetic contribution to senescence and longevity, and assesses the scale of the task that remains.

A network theory of ageing: the interactions of defective mitochondria, aberrant proteins, free radicals and scavengers in the ageing process

Evolution theory indicates that ageing is caused by progressive accumulation of defects, since the evolutionary optimal level of maintenance is always below the minimum required for indefinite survival. Evolutionary theories also suggest that multiple processes are operating in parallel, but unfortunately they make no predictions about specific mechanisms. To understand and evaluate the many different mechanistic theories of ageing which have been proposed, it is therefore important to understand and study the network of maintenance processes which control cellular homeostasis. In this paper we describe a Network Theory of Ageing which integrates the contributions of defective mitochondria, aberrant proteins, and free radicals to the ageing process, and which includes the protective effects of antioxidant enzymes and proteolytic scavengers. The model simulations not only confirm and explain many experimental, age related findings like an increase in the fraction of inactive proteins, a significant rise in protein half-life, an increase in the amount of damaged mitochondria, and a drop in the energy generation per mitochondrion, but they also show interactions between the different theories which could not have been observed without the network approach. In some simulations, for example, the mechanism of the final breakdown seems to be a consequence of the cooperation of mitochondrial and cytoplasmic reactions, the mitochondria being responsible for a long term, gradual change which eventually triggers a short lived cytoplasmic error loop.

Cycles, chaos, and evolution in virus cultures: a model of defective interfering particles

Defective interfering particles (DIP) are spontaneous deletion mutants of viruses that replicate at the expense of the parent virus. DIP have complex effects on the growth of viruses in vitro, including the establishment of persistent infection, cyclical variation in virus titer, eradication of replicating virus, and rapid evolution of the virus. We show here that a simple mathematical model, based only on experimental observations, can explain all of the major effects of DIP on the population dynamics of virus growth. The variation in virus titer caused by DIP has many features that are characteristic of deterministic chaos: it follows that the quantitative effects of DIP are intrinsically unpredictable beyond a short time. We conclude (i) that other factors, such as temperature-sensitive virus mutants or interferons, need not be invoked to explain the complex effects of DIP; and (ii) that dominantly interfering viruses should only be used with great caution for therapeutic purposes, since their effects are, in principle, unpredictable.

Towards a network theory of ageing: a model combining the free radical theory and the protein error theory

Many different theories of ageing have been proposed, based often on highly specific molecular causes. Recent advances in evolutionary theory support the idea that ageing is caused by progressive accumulation of defects, but indicate that multiple processes are likely to operate in parallel. This calls for an understanding of ageing and longevity in terms of a network of maintenance processes that controls the capability of the system to preserve homeostasis. Here we develop a theoretical model which begins the task of implementing a Network Theory of Ageing. To do this the model integrates the ideas of the Free Radical Theory, describing the reactions of free radicals, antioxidants and proteolytic enzymes, with the Protein Error Theory, describing the error propagation loops within the cellular translation machinery. The simulations show that an increased radical production and/or insufficient radical protection can destabilize an otherwise stable translation system. The model supports the idea that caloric restriction prolongs life via a reduction of the generation of radicals. Another result of the model is that protein half-life increases with time as a natural consequence of the interaction between proteolytic enzymes and radicals. Finally the model strengthens certain evolutionary ageing theories by showing that there is a positive correlation between maintenance related energy consumption and lifespan.

Defective interfering particles and virus evolution

Almost all viruses produce replication-defective mutants that have complex effects on the growth and evolution of the virus in culture. These effects can be explained qualitatively by a simple mathematical model. However, the model shows that the quantitative effects of these mutants are intrinsically unpredictable.

Mitochondrial mutations, cellular instability and ageing: modelling the population dynamics of mitochondria

All eukaryotic cells rely on mitochondrial respiration as their major source of metabolic energy (ATP). However, the mitochondria are also the main cellular source of oxygen radicals and the mutation rate of mtDNA is much higher than for chromosomal DNA. Damage to mtDNA is of great importance because it will often impair cellular energy production. However, damaged mitochondria can still replicate because the enzymes for mitochondrial replication are encoded entirely in the cell nucleus. For these reasons, it has been suggested that accumulation of defective mitochondria may be an important contributor to loss of cellular homoeostasis underlying the ageing process. We describe a mathematical model which treats the dynamics of a population of mitochondria subject to radical-induced DNA mutations. The model confirms the existence of an upper threshold level for mutations beyond which the mitochondrial population collapses. This threshold depends strongly on the division rate of the mitochondria. The model also reproduces and explains (i) the decrease in mitochondrial population with age, (ii) the increase in the fraction of damaged mitochondria in old cells, (iii) the increase in radical production per mitochondrion, and (iv) the decrease in ATP production per mitochondrion.

Accuracy of tRNA charging and codon: anticodon recognition; relative importance for cellular stability

Cellular homeostasis and the mechanisms which control homeostasis are important for understanding such fundamental processes as ageing and the origin of life. Several models have studied the importance of accurate protein synthesis for cellular stability, but these models have not considered the complexities of the translation process in any detail. Here we develop a new model which describes the interplay between aminoacyl-tRNA (aatRNA) synthetases, the cellular pool of charged tRNAs and the process of codon: anticodon recognition. We also take the processive character of the ribosomes into account. In common with previous work, our model predicts that the cellular translation apparatus can either be stable or deteriorate progressively with time. However, because our model explicitly describes different subreactions of the overall translation process, we are also able to assess the relative importance of accurate tRNA charging and codon: anticodon recognition for cellular stability. It appears that the tRNA charging by the aatRNA synthetases plays the key role in controlling the long-term stability of the cell. Ribosomal errors are less important because error-prone ribosomes, being processive, produce mainly inactive proteins which do not contribute to error propagation within the translation machinery.

Comparative life spans of species: why do species have the life spans they do?

Proximate answers to questions about species longevity are to be found in the physiological processes that regulate duration of life. But what are these processes, and how are they themselves controlled? This leads to ultimate, evolutionary questions about longevity. What are the selection forces that favor one life span instead of another for a given species? To understand the evolution of life span we need also to understand the evolution of aging. A plausible hypothesis is that because of the requirement for reproduction, natural selection favors a strategy that invests fewer resources in maintenance of somatic cells and tissues than are necessary for indefinite survival. This "disposable soma" theory predicts that aging is due to the accumulation of unrepaired somatic defects and the primary genetic control of longevity operates through selection to raise or lower the investment in basic cellular maintenance systems in relation to the level of environmental hazard.

Neuronal precursor cells in the rat hippocampal formation contribute to more than one cytoarchitectonic area

We have tested the hypothesis that cell lineage restriction boundaries define the borders between cytoarchitectonic areas in the cerebral cortex. Clonally related cells were identified using a retroviral marking technique, and the dispersion of neuronal clones was examined with respect to the transitions between cortical areas. We chose to study the hippocampal formation because we found that clones of hippocampal neurons, unlike those in neocortex, are compact and readily identifiable in the adult and that transitions between areas in the hippocampus are sharp relative to the spread of a typical clone. We conclude, contrary to the hypothesis, that clones of neurons transgress the boundaries between areas in the hippocampal formation, that border-crossing clones are observed as frequently as would be expected if clones spread freely over the hippocampus with no constraint imposed by area borders, and that different types of pyramidal neurons, characteristic of different areas, may appear to a single clone. different areas, may appear in a single clone.

The genetic contribution to human T-cell receptor repertoire

Recent studies in mice have highlighted the importance of polymorphic genetic loci such as the major histocompatibility complex (MHC) or minor lymphocyte-stimulating antigen (Mls) in determining the nature of the peripheral T-cell receptor (TcR) population. As our knowledge of the equivalent process in humans is incomplete, we have utilized a modification of the polymerase chain reaction (PCR) to determine the overall genetic contribution to the normal human TcR variable V beta gene repertoire. These data demonstrate that the normal human T-cell population contains members of all the major TcR V beta families and that there is considerable variation in the relative amounts of specific TcR V beta transcripts between individuals. We have established that the normal peripheral TcR V beta repertoire is more concordant in identical twins than in unrelated individuals. The relative importance of genetic factors in determining the peripheral TcR repertoire is emphasized by these results and suggests that, in humans, the genetic control of immune responsiveness is mediated in part by the peripheral TcR repertoire.

Evolution of senescence: late survival sacrificed for reproduction

In so far as it is associated with declining fertility and increasing mortality, senescence is directly detrimental to reproductive success. Natural selection should therefore act in the direction of postponing or eliminating senescence from the life history. The widespread occurrence of senescence is explained by observing that (i) the force of natural selection is generally weaker at late ages than at early ages, and (ii) the acquisition of greater longevity usually involves some cost. Two convergent theories are the 'antagonistic pleiotropy' theory, based in population genetics, and the 'disposable soma' theory, based in physiological ecology. The antagonistic pleiotropy theory proposes that certain alleles that are favoured because of beneficial early effects also have deleterious later effects. The disposable soma theory suggests that because of the competing demands of reproduction less effort is invested in the maintenance of somatic tissues than is necessary for indefinite survival.

Genetic basis of limited cell proliferation

Knowledge about the changes that occur as cells traverse their replicative lifespans grows apace, as evidenced by the articles in this issue. Controversy over the interpretation of this knowledge continues, however, and is indeed fuelled by new discoveries (e.g., see Cristofalo, 1990; Holliday, 1990; Smith, 1990). This paper makes a brief commentary on the problems of cellular ageing, with particular emphasis on the unfolding picture of the genetic control of ageing and longevity which derives from evolutionary theory (Kirkwood and Rose, 1991). The case is argued for a synthetic view which recognizes that the immediate causes of limited cell proliferation probably involve some form of active genetic control, but that the ultimate reason for cell ageing is found in evolutionary theories which suggest that the ageing process is not actively programmed and that senescence may be due to the accumulation of damage.

Tests for the statistical significance of protein sequence similarities in data-bank searches

A suite of tests to evaluate the statistical significance of protein sequence similarities is developed for use in data bank searches. The tests are based on the Wilbur-Lipman word-search algorithm, and take into account the sequence lengths and compositions, and optionally the weighting of amino acid matches. The method is extended to allow for the existence of a sequence insertion/deletion within the region of similarity. The accuracy of statistical distributions underlying the tests is validated using randomly generated sequences and real sequences selected at random from the data banks. A computer program to perform the tests is briefly described.