Muscle-specific expression of Drosophila hsp70 in response to aging and oxidative stress

Transgenic methods for increasing Drosophila life span

At least five different transgenic approaches have been applied to the study of Drosophila aging. There are two single component systems: transgenes with native (normal) promoters and transgenes with heterologous promoters; as well as three binary systems: 'GAL4/UAS', 'FLP-out' and 'tet-on'. These approaches vary in ability to meet several technical challenges, and the relative advantages and disadvantages of each are discussed. Using these techniques, over-expression of the hsp70, Cu/ZnSOD and MnSOD genes has each been demonstrated to increase Drosophila life span.

Hsp72 antigen expression in the proliferative compartment of involved psoriatic epidermis

Oxidative damage to growth regulatory proteins has been implicated in the aetiology of psoriasis. However, the transient synthesis of heat shock proteins has been shown to protect cells against the adverse effects of oxidative and other forms of physiological stress. This study has used an hsp72 monoclonal antibody to measure inducible 72 kDa heat shock protein expression in heat stressed normal human skin and established plaque psoriasis. Hsp72 was detected in the basal and suprabasal layer cells of heat-stressed normal skin, and in 12 involved psoriasis lesions. Hsp72 expression was not detected in unstressed normal skin or in 12 cases of uninvolved psoriasis. Immunoprecipitation and Western blotting of cell lysates from heat stressed normal skin and involved psoriasis lesions confirmed the presence of a 72 kDa polypeptide with hsp72 immunoreactivity. The MIB-1 monoclonal antibody was used to determine the proliferative fraction of normal and involved psoriastic epidermis. The Ki67 antigen was localised to the nuclei of basal and suprabasal layer cells of normal and involved psoriatic epidermis. Involved psoriatic epidermis contained a higher number of proliferating keratinocytes when compared with normal skin. The study has also demonstrated a strong correlation between hsp72 expression and keratinocyte proliferation in involved psoriatic epidermis (r=0.864, p<0.001). We believe that the 72 kDa inducible heat shock protein performs a protective function in the proliferative compartment of normal and involved psoriatic skin.

Stress resistance and longevity in selected lines of Drosophila melanogaster

Five independent populations (lines) of Drosophila melanogaster were selected for female starvation resistance. Females and males from the selected lines were relatively starvation resistant when compared to flies from five control lines. Moreover, flies from selected lines were resistant to other stresses: desiccation, acetone fumes, ethanol fumes, and paraquat (a source of oxygen radicals). Data from a variety of previous studies indicate an association between stress resistance and longevity. In this context, the present study addressed the question of whether flies from the stress-resistant lines were relatively long-lived. Replicate population cages from each selected and control line were used to assess longevity. Neither females nor males from the selected lines were relatively long-lived. In at least some cases, stress resistance may be necessary, but not sufficient, for longevity.

Sequence requirements for upregulated expression of Drosophila hsp70 transgenes during aging

hsp70 protein and hsp70:lacZ fusion reporters are upregulated during aging and in response to oxidative stress in the thorax of Drosophila. hsp70 expression was increased during aging in each of seven different Drosophila genetic backgrounds tested, 2.6-4.8-fold. DNA sequence requirements were investigated by analysis of nine distinct hsp70:lacZ fusion reporter constructs in multiple independent transgenic lines. hsp70 sequences -194 to +276 supported an average 2.7-fold increase during aging. This increase was reduced or eliminated by deletion or point mutation of the heat shock response elements, consistent with a transcriptional mechanism. Similar sequence requirements were observed for increased expression in response to catalase null mutation as a model of oxidative stress. hsp70 5'UTR sequences were required for efficient basal expression of transgenes, but were not sufficient to confer detectable upregulation during aging. Inclusion of additional hsp70 coding region sequences from +276 to + 1011 created a larger hsp70:lacZ fusion protein and had two effects: dramatic reduction of the overall expression level of the fusion protein, and an additional three to fourfold upregulation during aging. These results suggest that the coding region sequences reduce fusion protein abundance and that this negative effect decreases as a function of age. The data support a model for increased expression of hsp70 transgenes during aging involving both transcriptional and posttranscriptional components.

Transgenes in the Analysis of Life Span and Fitness

Drosophila P element-mediated transformation can be used to determine whether and how a specific gene contributes to demographic components of fitness. Motivated by the problem of senescence, researchers have applied this approach to genes thought to affect survival through processes of somatic maintenance. Cu/Zn-superoxide dismutase and catalase reduce the flux of reactive oxygen molecules that are thought to be a central cause of aging. EF1α is a component of the protein synthesis machine; deterioration of this housekeeping function is a potential contributor to senescence. Molecular chaperones such as the heat shock protein hsp70 are multifunctional molecules that affect a cell's response to acute stress. In some models, senescence results from the cumulative effects of stress, and heat shock proteins may regulate the progress of this deterioration. Transformations with the candidate genes of these proteins were used in independent studies to measure the effect of overexpression on longevity; positive results were reported. Here, I discuss the robustness of these results. I use the studies of superoxide dismutase, catalase, and EF1α to illustrate how the mutagenic effects of inserts confound our interpretations. I present new data from a reported study of hsp70 overexpression to show how engineered constructs can be used to overcome mutagenic artifacts through the controlled excision of sequences or alleles. The data for hsp70 provide the first strong molecular evidence that somatic maintenance affects longevity. Finally, future potential uses of transformation with Drosophila are discussed. I consider how metabolic control theory predicts that overexpression of genes for enzymes of intermediary metabolism is not likely to produce analytically useful changes in components of fitness.

HSP70 induction may explain the long-lasting resistance to heat of Drosophila melanogaster having lived in hypergravity

In this study, we showed that in flies kept for 2 weeks at 1 (terrestrial gravity), 3 or 5 x g (hypergravity, HG) before transfer to 1 x g, resistance to heat remained higher in HG flies for several weeks after the transfer. The measurement of heat shock protein 70 (hsp70) indicated no induction of the protein in HG, but the study revealed that flies living in HG expressed more hsp70 only after being submitted to severe stress. The higher induction of hsp70 may explain the higher thermotolerance of these HG-treated young flies. Finally, an unknown protein was observed only in females. This protein may belong to a class of higher molecular weight hsp (hsp110), which have not previously been observed in Drosophila.

Heat-shock proteins, molecular chaperones, and the stress response: evolutionary and ecological physiology

Molecular chaperones, including the heat-shock proteins (Hsps), are a ubiquitous feature of cells in which these proteins cope with stress-induced denaturation of other proteins. Hsps have received the most attention in model organisms undergoing experimental stress in the laboratory, and the function of Hsps at the molecular and cellular level is becoming well understood in this context. A complementary focus is now emerging on the Hsps of both model and nonmodel organisms undergoing stress in nature, on the roles of Hsps in the stress physiology of whole multicellular eukaryotes and the tissues and organs they comprise, and on the ecological and evolutionary correlates of variation in Hsps and the genes that encode them. This focus discloses that (a) expression of Hsps can occur in nature, (b) all species have hsp genes but they vary in the patterns of their expression, (c) Hsp expression can be correlated with resistance to stress, and (d) species' thresholds for Hsp expression are correlated with levels of stress that they naturally undergo. These conclusions are now well established and may require little additional confirmation; many significant questions remain unanswered concerning both the mechanisms of Hsp-mediated stress tolerance at the organismal level and the evolutionary mechanisms that have diversified the hsp genes.

Aging-specific expression of Drosophila hsp22

hsp22 is among the least abundantly expressed Drosophila heat shock (hs) genes during both development and heat stress. In contrast, hsp22 was found to be the most abundantly expressed hs gene during Drosophila aging. During aging, hsp22 RNA was induced 60-fold in the head, with somewhat lower level induction in abdomen and thorax. Induction of the other hs gene RNAs was </=3-fold, except for hsp23, which was induced approximately 5-fold in thorax. hsp22 protein was detected using rat anti-hsp22 polyclonal antisera and was induced >150-fold, with particularly abundant expression in eye tissue. Aging-specific induction of hsp22 was reproduced by hsp22:lacZ fusion reporter constructs in transgenic flies. Analysis of specific promoter mutations in transgenic flies indicated that functional heat shock response elements are required for hsp22 induction during aging. Finally, comparison of hsp22 RNA and protein expression patterns suggests that aging-specific expression of hsp22 is regulated at both the transcriptional and the posttranscriptional levels. Aging-specific induction of hsp22 is discussed with regard to current evolutionary theories of aging.

FLP recombinase-mediated induction of Cu/Zn-superoxide dismutase transgene expression can extend the life span of adult Drosophila melanogaster flies

Yeast FLP recombinase was used in a binary transgenic system ("FLP-OUT") to allow induced overexpression of catalase and/or Cu/Zn-superoxide dismutase (Cu/ZnSOD) in adult Drosophila melanogaster. Expression of FLP recombinase was driven by the heat-inducible hsp70 promoter. Once expressed, FLP catalyzed the rearrangement and activation of a target construct in which expression of catalase or Cu/ZnSOD cDNAs was driven by the constitutive actin5C promoter. In this way a brief heat pulse (120 or 180 min, total) of young adult flies activated transgene expression for the rest of the life span. FLP-OUT allows the effects of induced transgene expression to be analyzed in control (no heat pulse) and experimental (heat pulse) populations with identical genetic backgrounds. Under the conditions used, the heat pulse itself always had neutral or slightly negative effects on the life span. Catalase overexpression significantly increased resistance to hydrogen peroxide but had neutral or slightly negative effects on the mean life span. Cu/ZnSOD overexpression extended the mean life span up to 48%. Simultaneous overexpression of catalase with Cu/ZnSOD had no added benefit, presumably due to a preexisting excess of catalase. The data suggest that oxidative damage is one rate-limiting factor for the life span of adult Drosophila. Finally, experimental manipulation of the genetic background demonstrated that the life span is affected by epistatic interactions between the transgene and allele(s) at other loci.

Heat stress-induced life span extension in yeast

The yeast Saccharomyces cerevisiae has a limited life span that can be measured by the number of times individual cells divide. Several genetic manipulations have been shown to prolong the yeast life span. However, environmental effects that extend longevity have been largely ignored. We have found that mild, nonlethal heat stress extended yeast life span when it was administered transiently early in life. The increased longevity was due to a reduction in the mortality rate that persisted over many cell divisions (generations) but was not permanent. The genes RAS1 and RAS2 were necessary to observe this effect of heat stress. The RAS2 gene is consistently required for maintenance of life span when heat stress is chronic or in its extension when heat stress is transient or absent altogether. RAS1, on the other hand, appears to have a role in signaling life extension induced by transient, mild heat stress, which is distinct from its life-span-curtailing effect in the absence of stress and its lack of involvement in the response to chronic heat stress. This distinction between the RAS genes may be partially related to their different effects on growth-promoting genes and stress-responsive genes. The ras2 mutation clearly hindered resumption of growth and recovery from stress, while the ras1 mutation did not. The HSP104 gene, which is largely responsible for induced thermotolerance in yeast, was necessary for life extension induced by transient heat stress. An interaction between mitochondrial petite mutations and heat stress was found, suggesting that mitochondria may be necessary for life extension by transient heat stress. The results raise the possibility that the RAS genes and mitochondria may play a role in the epigenetic inheritance of reduced mortality rate afforded by transient, mild heat stress.

Extended life-span and stress resistance in the Drosophila mutant methuselah

Toward a genetic dissection of the processes involved in aging, a screen for gene mutations that extend life-span in Drosophila melanogaster was performed. The mutant line methuselah (mth) displayed approximately 35 percent increase in average life-span and enhanced resistance to various forms of stress, including starvation, high temperature, and dietary paraquat, a free-radical generator. The mth gene predicted a protein with homology to several guanosine triphosphate-binding protein-coupled seven-transmembrane domain receptors. Thus, the organism may use signal transduction pathways to modulate stress response and life-span.

Identification of stress-responsive genes in Caenorhabditis elegans using RT-PCR differential display

In order to identify genes that are differentially expressed as a consequence of oxidative stress due to paraquat we used the differential display technique to compare mRNA expression patterns in Caenorhabditis elegans . A C.elegans mixed stage worm population and a homogeneous larval population were treated with 100 mM paraquat, in parallel with controls. Induction of four cDNA fragments, designated L-1, M-47, M-96 and M-132, was confirmed by Northern blot analysis with RNA from stressed and unstressed worm populations. A 40-fold increase in the steady-state mRNA level in the larval population was observed for the L-1/M-47 gene, which encodes the detoxification enzyme glutathione S-transferase. A potential stress-responsive transcription factor (M-132) with C2H2-type zinc finger motifs and an N-terminal leucine zipper domain was identified. The M-96 gene encodes a novel stress-responsive protein. Since paraquat is known to generate superoxide radicals in vivo , the response of the C.elegans superoxide dismutase (SOD) genes to paraquat was also investigated in this study. The steady-state mRNA levels of the manganese-type and the copper/zinc-type SODs increased 2-fold in the larval population in response to paraquat, whereas mixed stage populations did not show any apparent increase in the levels of these SOD mRNAs.

DNA mismatch repair catalyzed by extracts of mitotic, postmitotic, and senescent Drosophila tissues and involvement of mei-9 gene function for full activity

Extracts of Drosophila embryos and adults have been found to catalyze highly efficient DNA mismatch repair, as well as repair of 1- and 5-bp loops. For mispairs T.G and G.G, repair is nick dependent and is specific for the nicked strand of heteroduplex DNA. In contrast, repair of A.A, C.A, G.A, C.T, T.T, and C.C is not nick dependent, suggesting the presence of glycosylase activities. For nick-dependent repair, the specific activity of embryo extracts was similar to that of extracts derived from the entirely postmitotic cells of young and senescent adults. Thus, DNA mismatch repair activity is expressed in Drosophila cells during both development and aging, suggesting that there may be a function or requirement for mismatch repair throughout the Drosophila life span. Nick-dependent repair was reduced in extracts of animals mutant for the mei-9 gene. mei-9 has been shown to be required in vivo for certain types of DNA mismatch repair, nucleotide excision repair (NER), and meiotic crossing over and is the Drosophila homolog of the yeast NER gene rad1.

Heat shock proteins (HSP70) as biomarkers in ecotoxicological studies

Hsp70, so-called stress proteins, were studied in the centipede Lithobius mutabilis when exposed in laboratory tests to different concentrations of the insecticide dimethoate (DMT; 0, 0.012, 0.111 mg kg-1 dwt), the detergent linear alkilobenzene sulfonate (LAS; 0, 16, 80, 400, 2000, 10,000 mg kg-1 dwt), and copper (Cu; 0, 56, 167, 500, 1000, 1500 mg kg-1 dwt) and in the field in captured animals from polluted (2 and 4 km from a zinc-and-lead smelter) and unpolluted (35 and 40 km from the smelter) areas. Hsp70 in centipedes were also tested for seasonal differences (March and September) in field-captured animals and for a temperature effect under laboratory conditions (5, 15, and 25 degrees C). Moreover, hsp70 were examined in housefly (Musca domestica) pupae after rearing larvae on food medium contaminated with DMT or LAS. Hsp70 were found in all animals tested, including controls, and their levels were not clearly related to the laboratory treatment with chemicals or temperature or to the degree of contamination in polluted areas. In centipedes from unpolluted areas, a significant seasonal difference in hsp70 content was found. The problems with using hsp70 as a universal biomarker in ecotoxicological studies are discussed.

Role of Mitochondria in Human Aging

Mitochondria are the major intracellular source and target sites of reactive oxygen species (ROS) that are continually generated as by-products of aerobic metabolism in animal and human cells. It has been demonstrated that mitochondrial respiratory function declines with age in various human tissues and that a defective respiratory chain results in enhanced production of ROS and free radicals in mitochondria. On the other hand, accumulating evidence now indicates that lipid peroxidation, protein modification and mitochondrial DNA (mtDNA) mutation are concurrently increased during aging. On the basis of these observations and the fact that the rate of cellular production of superoxide anions and hydrogen peroxide increases with age, it has recently been postulated that oxidative stress is a major contributory factor in the aging process. A causal relationship between oxidative modification and mutation of mtDNA, mitochondrial dysfunction and aging has emerged, although some details have remained unsolved. In this article, the role of mitochondria in the human aging process is reviewed on the basis of recent findings gathered from our and other laboratories.

Genetics of aging

The role of genetics in determining life-span is complex and paradoxical. Although the heritability of life-span is relatively minor, some genetic variants significantly modify senescence of mammals and invertebrates, with both positive and negative impacts on age-related disorders and life-spans. In certain examples, the gene variants alter metabolic pathways, which could thereby mediate interactions with nutritional and other environmental factors that influence life-span. Given the relatively minor effect and variable penetrance of genetic risk factors that appear to affect survival and health at advanced ages, life-style and other environmental influences may profoundly modify outcomes of aging.

Biochemical analysis of the stress protein response in human oesophageal epithelium

BACKGROUND

The oesophageal epithelium is exposed routinely to noxious agents in the environment, including gastric acid, thermal stress, and chemical toxins. These epithelial cells have presumably evolved effective protective mechanisms to withstand tissue damage and repair injured cells. Heat shock protein or stress protein responses play a central role in protecting distinct cell types from different types of injury.

AIM

To determine (i) whether biochemical analysis of stress protein responses in pinch biopsy specimens from human oesophageal epithelium is feasible; (ii) whether undue stresses are imposed on cells by the act of sample collection, thus precluding analysis of stress responses; and (iii) if amenable to experimentation, the type of heat shock protein (Hsp) response that operates in the human oesophageal epithelium.

METHODS

Tissue from the human oesophagus comprised predominantly of squamous epithelium was acquired within two hours of biopsy and subjected to an in vitro heat shock. Soluble tissue cell lysates derived from untreated or heat shocked samples were examined using denaturing polyacrylamide gel electrophoresis for changes in: (i) the pattern of general protein synthesis by labelling epithelial cells with 35S-methionine and (ii) the levels of soluble Hsp70 protein and related isoforms using immunochemical protein blots.

RESULTS

A single pinch biopsy specimen is sufficient to extract and analyse specific sets of polypeptides in the oesophageal epithelium. After ex vivo heat shock, a classic inhibition of general protein synthesis is observed and correlates with the increased synthesis of two major proteins of molecular weight of 60 and 70 kDa. Notably, cells from unheated controls exhibit a "stressed" biochemical state 22 hours after incubation at 37 degrees C, as shown by inhibition of general protein synthesis and increased synthesis of the 70 kDa protein. These data indicate that only freshly acquired specimens are suitable for studying stress responses ex vivo. No evidence was found that the two heat induced polypeptides are previously identified Hsp70 isoforms. In fact, heat shock results in a reduction in the steady state concentrations of Hsp70 protein in the oesophageal epithelium.

CONCLUSION

Systematic and highly controlled studies on protein biochemistry are possible on epithelial biopsy specimens from the human oesophagus. These technical innovations have permitted the discovery of a novel heat shock response operating in the oesophageal epithelium. Notably, two polypeptides were synthesised after heat shock that seem to differ from Hsp70 protein. In addition, the striking reduction in steady state concentrations of Hsp70 protein after heat shock suggests that oesophageal epithelium has evolved an atypical biochemical response to thermal stress.

Drosophila drop-dead mutations accelerate the time course of age-related markers

Mutations of the drop-dead gene in Drosophila melanogaster lead to striking early death of the adult animal. At different times, after emergence from the pupa, individual flies begin to stagger and, shortly thereafter, die. Anatomical examination reveals gross neuropathological lesions in the brain. The life span of flies mutant for the drop-dead gene is four to five times shorter than for normal adults. That raises the question whether loss of the normal gene product might set into motion a series of events typical of the normal aging process. We used molecular markers, the expression patterns of which, in normal flies, change with age in a manner that correlates with life span. In the drop-dead mutant, there is an acceleration in the temporal pattern of expression of these age-related markers.

alpha-Melanocyte stimulating hormone downregulates differentiation-driven heat shock protein 70 expression in keratinocytes

Heat shock proteins are versatile tools engaged in several cellular functions. In particular, the stress-inducible 70-kDa heat shock protein (hsp70) not only confers protection on cells but also is involved in the regulation of the production of cellular stress response mediators including cytokines. In addition to cytokines, neurohormones such as alpha-melanocyte stimulating hormone (alphaMSH) were recently found to be potent mediators of inflammatory and immune responses. Thus, the current study was performed to investigate the role of alphaMSH in the expression of hsp70 in a human keratinocyte cell line (HaCaT). Proliferation and differentiation of HaCaT cells are known to be regulated by changing extracellular Ca2+ concentrations. HaCaT cells induced to differentiate in high Ca2+ medium (1.5 mM) were found to express higher levels of hsp70 protein than cells grown under low Ca2+ conditions. Moreover, differentiated HaCaT cells were markedly more resistant to oxidative stress than undifferentiated control cells. alphaMSH significantly suppressed hsp70 expression in a concentration-dependent manner in differentiated HaCaT cells but had only a minor effect on undifferentiated cells. Upon treatment with alphaMSH, HaCaT cells grown in high Ca2+ medium were rendered more sensitive to oxidative stress, which significantly decreased their survival rate. These findings indicate that alphaMSH, which is released by keratinocytes in an autocrine fashion following injurious stimuli such as tumor promoters or ultraviolet light, is able to regulate the cells' cytoprotective protein equipment.

Spatial and temporal pattern of expression of the wingless and engrailed genes in the adult antenna is regulated by age-dependent mechanisms

The spatial and temporal pattern of expression of enhancer trap lines reporting on the wingless (wg) and engrailed (en) genes was characterized in the adult antenna of Drosophila melanogaster. The time courses of expression seen for wg and en, although different from each other, reveal a complex well-controlled pattern of temporal expression, providing evidence that regulatory mechanisms are preserved throughout the life span of the adult fly. Altering the life span demonstrates that the temporal patterns of expression of both wg and en are linked to life span. These studies suggest that the expression of wg and en in the adult antenna is controlled by age-dependent mechanisms.

Aging mechanisms in fruit files

Genetic analysis of Drosophila has provided evidence in support of two proposed evolutionary genetic mechanisms of aging: mutation accumulation and antagonistic pleiotropy. Both mechanisms result from the lack of natural selection acting on old organisms. Analyses of large numbers of files have revealed that mortality rates do not continue to rise with age as previously thought, but plateau at advanced ages. This phenomenon has implications both for models and for definitions of aging, and may be explained by the evolutionary theories. The physiological processes and genes most relevant to aging are being identified using Drosophila lines selected in the laboratory for postponed senescence. Oxidative stress and insufficient metabolic reserves/capacity may be particularly important factors in limiting the fruitfly lifespan. Genes which exhibit aging-related changes in expression are now being identified. Transgenic files are being used to analyze the mechanisms of such aging-related gene expression, and to test the effects of specific genes on aging and aging-related deterioration.

Invertebrate gerontology: the age mutations of Caenorhabditis elegans

Ageing is a complex phenomenon which remains a major challenge to modern biology. Although the evolutionary biology of ageing is well understood, the mechanisms that limit lifespan are unknown. The isolation and analysis of single-gene mutations which extend lifespan (Age mutations) is likely to reveal processes which influence ageing. Caenorhabditis elegans is the only metazoan in which Age mutations have been identified. The Age mutations not only prolong life, but also confer a complex array of other phenotypes. Some of these phenotypes provide clues to the evolutionary origins of these genes while others allude to mechanisms of lifespan-extension. Many of the Age genes interact and share a second common phenotype, that of stress resistance. Rather than invertebrate ageing being determined by a 'clock mechanism', a picture is emerging of ageing as a non-adaptive process determined, in part, by resistance to intrinsic stress mediated by stress-response genes.

Timing of expression of a gene in the adult Drosophila is regulated by mechanisms independent of temperature and metabolic rate

The examination of beta-galactosidase (beta-gal) expression in the third segment of the antenna of the 2216 enhancer trap line in Drosophila melanogaster reveals two distinct spatial and temporal regulatory patterns of expression during adult life. Type 1 expression is characterized by a decline in the level of beta-gal expression with increasing age. Starting from a maximal level of expression at the time of adult emergence, there is a decrease in the number of cells that express beta-gal so that by 40-50 days of adult life few cells express beta-gal. Varying the ambient temperature and using hyperactivity mutants (Hyperkinetic, Shaker) demonstrates that the rate of this decline is independent of temperature and metabolic rate. Type II expression is distinctly different in spatial distribution and temporal regulation from the first pattern. Type II expression is restricted in the antenna to a small (< 20-30) set of cells whose level of expression changes in a periodic manner with time. The regulation of this periodicity appears to be linked to ambient temperature.

Longevity, genes, and aging

Until recently, biogerontology was a backwater of biology, but progress in the qualitative and quantitative genetic analysis of longevity has led to a revolution in aging research. This research has revealed that extended longevity is frequently associated with enhanced metabolic capacity and response to stress. Moreover, it suggests that there are multiple mechanisms of aging. Because of its complexity, the aging process takes us into the realm of integrative biology, and thus, biogerontology should prove instrumental in deciphering the functional and regulatory circuitry of the sequenced genome.