Regulation of the p19Arf/p53 pathway by histone acetylation underlies neural stem cell behavior in senescence‐prone SAMP8 mice

Brain aging is associated with increased neurodegeneration and reduced neurogenesis. B1/neural stem cells (B1‐NSCs) of the mouse subependymal zone (SEZ) support the ongoing production of olfactory bulb interneurons, but their neurogenic potential is progressively reduced as mice age. Although age‐related changes in B1‐NSCs may result from increased expression of tumor suppressor proteins, accumulation of DNA damage, metabolic alterations, and microenvironmental or systemic changes, the ultimate causes remain unclear. Senescence‐accelerated‐prone mice (SAMP8) relative to senescence‐accelerated‐resistant mice (SAMR1) exhibit signs of hastened senescence and can be used as a model for the study of aging. We have found that the B1‐NSC compartment is transiently expanded in young SAMP8 relative to SAMR1 mice, resulting in disturbed cytoarchitecture of the SEZ, B1‐NSC hyperproliferation, and higher yields of primary neurospheres. These unusual features are, however, accompanied by premature loss of B1‐NSCs. Moreover, SAMP8 neurospheres lack self‐renewal and enter p53‐dependent senescence after only two passages. Interestingly, in vitro senescence of SAMP8 cells could be prevented by inhibition of histone acetyltransferases and mimicked in SAMR1 cells by inhibition of histone deacetylases (HDAC). Our data indicate that expression of the tumor suppressor p19, but not of p16, is increased in SAMP8 neurospheres, as well as in SAMR1 neurospheres upon HDAC inhibition, and suggest that the SAMP8 phenotype may, at least in part, be due to changes in chromatin status. Interestingly, acute HDAC inhibition in vivo resulted in changes in the SEZ of SAMR1 mice that resembled those found in young SAMP8 mice.     

Trimethylamine‐N‐oxide promotes brain aging and cognitive impairment in mice

Gut microbiota can influence the aging process and may modulate aging‐related changes in cognitive function. Trimethylamine‐N‐oxide (TMAO), a metabolite of intestinal flora, has been shown to be closely associated with cardiovascular disease and other diseases. However, the relationship between TMAO and aging, especially brain aging, has not been fully elucidated. To explore the relationship between TMAO and brain aging, we analysed the plasma levels of TMAO in both humans and mice and administered exogenous TMAO to 24‐week‐old senescence‐accelerated prone mouse strain 8 (SAMP8) and age‐matched senescence‐accelerated mouse resistant 1 (SAMR1) mice for 16 weeks. We found that the plasma levels of TMAO increased in both the elderly and the aged mice. Compared with SAMR1‐control mice, SAMP8‐control mice exhibited a brain aging phenotype characterized by more senescent cells in the hippocampal CA3 region and cognitive dysfunction. Surprisingly, TMAO treatment increased the number of senescent cells, which were primarily neurons, and enhanced the mitochondrial impairments and superoxide production. Moreover, we observed that TMAO treatment increased synaptic damage and reduced the expression levels of synaptic plasticity‐related proteins by inhibiting the mTOR signalling pathway, which induces and aggravates aging‐related cognitive dysfunction in SAMR1 and SAMP8 mice, respectively. Our findings suggested that TMAO could induce brain aging and age‐related cognitive dysfunction in SAMR1 mice and aggravate the cerebral aging process of SAMP8 mice, which might provide new insight into the effects of intestinal microbiota on the brain aging process and help to delay senescence by regulating intestinal flora metabolites.     

Senescence-Accelerated Mouse (SAM) with Special References to Neurodegeneration Models,SAMP8 and SAMP10 Mice

The SAM strains, a group of related inbred strains consisting of senescence-prone inbred strains (SAMP) and senescence-resistant inbred strains (SAMR), have been successfully developed by selective inbreeding of the AKR/J strain of mice donated by the Jackson laboratory in 1968. The characteristic feature of aging common to the SAMP and SAMR is accelerated senescence and normal aging, respectively. Furthermore, SAMP and SAMR strains of mice manifest various pathobiological phenotypes spontaneously. Among SAMP strains, SAMP8 and SAMP10 mice show age-related behavioral deterioration such as deficits in learning and memory, emotional disorders (reduced anxiety-like behavior and depressive behavior) and altered circadian rhythm associated with certain pathological, biochemical and pharmacological changes. Here, the previous and recent literature on SAM mice are reviewed with an emphasis on SAMP8 and SAMP10 mice. A spontaneous model like SAM with distinct advantages over the gene-modified model is hoped by investigators to be used more widely as a biogerontological resource to explore the etiopathogenesis of accelerated senescence and neurodegenerative disorders.     

The Senescence-accelerated Mouse (SAM): A Higher Oxidative Stress and Age-dependent Degenerative Diseases Model

The SAM strain of mice is actually a group of related inbred strains consisting of a series of SAMP (accelerated senescence-prone) and SAMR (accelerated senescence-resistant) strains. Compared with the SAMR strains, the SAMP strains show a more accelerated senescence process, a shorter lifespan, and an earlier onset and more rapid progress of age-associated pathological phenotypes similar to human geriatric disorders. The higher oxidative stress status observed in SAMP mice is partly caused by mitochondrial dysfunction, and may be a cause of this senescence acceleration and age-dependent alterations in cell structure and function. Based on our recent observations, we discuss a possible mechanism for mitochondrial dysfunction resulting in the excessive production of reactive oxygen species, and a role for the hyperoxidative stress status in neurodegeneration in SAMP mice. These SAM strains can serve as a useful tool to understand the cellular mechanisms of age-dependent degeneration, and to develop clinical interventions. Special issue article in honor of Dr. Akitane Mori.     

Mechanisms of aging in senescence-accelerated mice

Background  

Progressive neurological dysfunction is a key aspect of human aging. Because of underlying differences in the aging of mice and humans, useful mouse models have been difficult to obtain and study. We have used gene-expression analysis and polymorphism screening to study molecular senescence of the retina and hippocampus in two rare inbred mouse models of accelerated neurological senescence (SAMP8 and SAMP10) that closely mimic human neurological aging, and in a related normal strain (SAMR1) and an unrelated normal strain (C57BL/6J).     

Diabetes exacerbates amyloid and neurovascular pathology in aging‐accelerated mice

Mounting evidence supports a link between diabetes, cognitive dysfunction, and aging. However, the physiological mechanisms by which diabetes impacts brain function and cognition are not fully understood. To determine how diabetes contributes to cognitive dysfunction and age‐associated pathology, we used streptozotocin to induce type 1 diabetes (T1D) in senescence‐accelerated prone 8 (SAMP8) and senescence‐resistant 1 (SAMR1) mice. Contextual fear conditioning demonstrated that T1D resulted in the development of cognitive deficits in SAMR1 mice similar to those seen in age‐matched, nondiabetic SAMP8 mice. No further cognitive deficits were observed when the SAMP8 mice were made diabetic. T1D dramatically increased Aβ and glial fibrillary acidic protein immunoreactivity in the hippocampus of SAMP8 mice and to a lesser extent in age‐matched SAMR1 mice. Further analysis revealed aggregated Aβ within astrocyte processes surrounding vessels. Western blot analyses from T1D SAMP8 mice showed elevated amyloid precursor protein processing and protein glycation along with increased inflammation. T1D elevated tau phosphorylation in the SAMR1 mice but did not further increase it in the SAMP8 mice where it was already significantly higher. These data suggest that aberrant glucose metabolism potentiates the aging phenotype in old mice and contributes to early stage central nervous system pathology in younger animals.     

Scrapie infection activates the replication of ecotropic, xenotropic, and polytropic murine leukemia virus (MuLV) in brains and spinal cords of senescence-accelerated mice: implication of MuLV in progression of scrapie pathogenesis

Senescence-accelerated mice (SAMP8) have a short life span, whereas SAMR1 mice are resistant to accelerated senescence. Previously it has been reported that the Akv strain of ecotropic murine leukemia virus (E-MuLV) was detected in brains of SAMP8 mice but not in brains of SAMR1 mice. In order to determine the change of MuLV levels following scrapie infection, we analyzed the E-MuLV titer and the RNA expression levels of E-MuLV, xenotropic MuLV, and polytropic MuLV in brains and spinal cords of scrapie-infected SAM mice. The expression levels of the 3 types of MuLV were increased in scrapie-infected mice compared to control mice; E-MuLV expression was detected in infected SAMR1 mice, but only in the terminal stage of scrapie disease. We also examined incubation periods and the levels of PrPSc in scrapie-infected SAMR1 (sR1) and SAMP8 (sP8) mice. We confirmed that the incubation period was shorter in sP8 (210+/-5 days) compared to sR1 (235+/-10 days) after intraperitoneal injection. The levels of PrPSc in sP8 were significantly greater than sR1 at 210+/-5 days, but levels of PrPSc at the terminal stage of scrapie in both SAM strains were virtually identical. These results show the activation of MuLV expression by scrapie infection and suggest acceleration of the progression of scrapie pathogenesis by MuLV.     

The effect of aging on the mineral status of female SAMP1 and SAMR1

The effect of aging on the status of macrominerals and trace elements in tissues was studied using two strains (SAMP1 and SAMR1) of senescence accelerated mouse. Two-month-old, 6-mo-old, and 10-mo-old female SAMP1 and SAMR1 mice were fed a commercial diet. Iron, zinc, copper, calcium, magnesium, phosphorus, sulfur, sodium, and potassium concentrations in blood, liver, kidney, brain, and tibia of the mice were determined. The copper concentration in the brain was significantly increased with age in SAMP1 and SAMR1. In addition, the brain copper levels in SAMP1 were significantly higher than that in SAMR1 at respective ages. The calcium concentration in the kidney was significantly increased with age, but the copper and phosphorus concentrations significantly decreased with age in SAMP1 and SAMR1. In the liver of SAMR1, all minerals measured in this study except for sodium and potassium were significantly decreased with age. In addition, all mineral concentrations in the liver of 2-mo-old mice in SAMR1 except for copper and sodium were markedly higher than those in SAMP1 of the same age. These results suggest that the genetic factor is related to the age-associated mineral changes in tissues.     

Age-related changes in blood pressure in the senescence-accelerated mouse (SAM): aged SAMP1 mice manifest hypertensive vascular disease

Age-related changes in systolic blood pressure were assessed, using the senescence-accelerated mouse (SAM) model for aging research with strains SAMR1, SAMP1, and SAMP8. Each of the strains manifested a characteristic change in blood pressure with age. The SAMR1 strain, with normal aging, did not have chronologic changes from 2 to 27 months of age. The SAMP1 strain, with accelerated senescence, had a significant increase in blood pressure with age, and some (8 of 39) mice manifested hypertensive vascular disease characterized by high blood pressure, cardiac hypertrophy, and arteriolar fibrinoid necrosis at 11 to 14 months of age. The gradual increase in blood pressure after 8 to 10 months was considered to be preceded by progressive renal changes, from glomerulonephritis to contraction of the kidney, suggesting that the high blood pressure in the SAMP1 strain was of renal origin. Blood pressure in the SAMP8 strain, with age-related deficits in learning and memory, gradually decreased after 5 to 7 months of age, and was suggested to be due to the astrogliotic changes in response to spongiform degeneration in the medulla oblongata at 11 to 14 and 15 to 18 months of age.     

Proliferative Senescence of Embryo Fibroblasts of Japanese Senescence Accelerated Mice is Accompanied by Parallel Decreasing of the Response to Various Growth Factors

The Japanese senescence accelerated mice (SAM) are a group of the low-longevity mouse lines and represent a new convenient model for studying the senescence process. We studied the proliferation of embryo fibroblasts of SAMP1 and SAMR1 mouse lines. It was shown that fibroblasts of the shortest longevity line SAMP1 have a markedly decreased proliferative potential of the mean 8.7 population doublings, whereas fibroblasts of a relatively high-longevity line SAMR1 have an average proliferative potential of 12.3 doublings. The fibroblast senescence in both lines is accompanied by simultaneous lowering of the cell proliferative response to the blood serum, epidermal, fibroblast, and platelet-derived growth factors. At initial stages of the cell culture growth, lines SAMP1 and SAMR1 exhibit the same reactions to growth factors, but already beginning from the fifth doubling, the SAMP1 cell response is sharply decreased as compared with SAMR1. Lowering of the proliferative reaction is accompanied by decreased phosphorylation of tyrosine in the cell proteins responsible for the mitogenic reaction. Thus, the parallel decrease in the proliferative response to different growth factors during fibroblast senescence is most likely due to the emergence of a regulatory block at common stages of the mitogenic signal transduction.     

A Biological Model of Accelerated Senescence. 1. The Rate of the Spontaneous Mutation Process in Spermatogenesis of Senescence-Accelerated Mice

We studied the dynamics of age-related cytogenetic changes in the developing male germ cells of mice prone to accelerated senescence (strain SAMP1) and mice resistant to accelerated senescence (strain SAMP1) by counting the spermatogonial and meiotic micronuclei and testing the defects of the spermatozoon head shape. In these animals, the accumulation of germinative mutations has a nonlinear pattern. During the entire ontogenesis of SAMP1 mice, the frequency of circular spermatids with micronuclei corresponded to the level observed upon induced mutagenesis.     

Proliferative senescence of embryo fibroblasts of Japanese senescence accelerated mice (SAM) is accompanied by parallel decreasing of response to various growth factors

The Japanese senescence accelerated mice (SAM) are a group of the low-longevity mouse lines and represent a new convenient model for studying the senescence process. We studied the proliferation of embryo fibroblasts of SAMP1 and SAMR1 mouse lines. It was shown that fibroblasts of the shortest longevity line SAMP1 have a markedly decreased proliferative potential of the mean 8.7 population doublings, whereas fibroblasts of a relatively high-longevity line SAMR1 have an average proliferative potential of 12.3 doublings. The fibroblast senescence in both lines is accompanied by a simultaneous lowering of the cell proliferative response to the blood serum, epidermal, fibroblast, and platelet-derived growth factors. At initial stages of the cell culture growth, lines SAMP1 and SAMR1 exhibit the same reactions to growth factors, but already beginning from the fifth doubling, the SAMP1 cell response is sharply decreased as compared with SAMR1. Lowering the proliferative reaction is accompanied by a decreased phosphorylation of tyrosine in the cell proteins responsible for mitogenic reaction. Thus, the parallel decrease of proliferative response to different growth factors during fibroblast senescence is most likely due the emergence of a regulatory block at common stages of the mitogenic signal transduction.     

Cytogenetic Aberrations in the Cells of Liver and Spermatogenic Epithelium in Senescence Accelerated SAMP1 and SAMR1 Mice

It was shown that during ontogenesis, the mice prone to (SAMP1) and resistant (SAMR1) against accelerates senescence did not differ substantially in the frequency of cytogenetic aberrations in the hepatocytes and spermatogenic cells (spermatogonia and round spermatids). These data suggest that in the mice of both lines, the processes of appearance, development, and functioning of complex biological systems, such as liver and spermatogonic epithelium take place against the background of high genetic instability. The role of genetic instability in senescence is discussed.     

Nanoindentation and whole-bone bending estimates of material properties in bones from the senescence accelerated mouse SAMP6

The senescence accelerated mouse, strain P6 (SAMP6) has been described as a model of senile osteoporosis. Recent results from whole-bone bending tests indicate that, despite having increased moments of inertia, SAMP6 long bones are weak and brittle compared to SAMR1 controls. In the current study we determined material properties of cortical bone from SAMP6 and SAMR1 femora and tibiae by two methods-nanoindentation and whole-bone bending tests combined with simple beam theory. We hypothesized that: (1) SAMP6 mice have reduced cortical bone material properties compared to SAMR1 controls; and (2) modulus estimated from whole-bone bending tests correlates well with modulus determined by nanoindentation. Results from nanoindentation indicated that modulus and hardness are approximately 10% higher in SAMP6 mice compared to SAMR1 controls (p<0.001), a finding consistent with slightly higher mineralization in SAMP6 bones. Despite their superior elastic and hardness properties, the bending failure properties of SAMP6 bones were markedly inferior--ultimate stress and toughness were reduced by 40% and 60%, respectively (p<0.001). Comparisons between the two testing methods for determining modulus showed poor agreement. Modulus estimated from whole-bone bending tests was not correlated with modulus determined by nanoindentation (p=0.054; r2=0.03) and the absolute values differed by a factor of five between the two methods (bending [wet], 6GPa; nanoindentation [dry], 31GPa). Moreover, relative differences between groups were inconsistent between the two methods. We conclude: (1) cortical bone from the SAMP6 mouse has increased modulus and hardness but poor material strength and toughness, which underscores the relevance of the SAMP6 mouse for studies of skeletal fragility, and (2) values of elastic modulus of bone tissue estimated using simple beam theory and bending tests of mouse femora and tibiae are inaccurate and should be interpreted with caution.     

The level of butyrylcholinesterase activity increases and the content of the mRNA remains unaffected in brain of senescence-accelerated mouse SAMP8

Looking at cholinesterases (ChEs) changes in age-related mental impairment, the expression of ChEs in brain of senescence accelerated-resistant (SAMR1) and senescence accelerated-prone (SAMP8) mice was studied. Acetylcholinesterase (AChE) activity was unmodified and BuChE activity increased twofold in SAMP8 brain. SAMR1 brain contained many AChE-T mRNAs, less BuChE and PRiMA mRNAs and scant AChE-R and AChE-H mRNAs. Their content unchanged in SAMP8 brain. Amphiphilic (G(4)(A)) and hydrophilic (G(4)(H)) AChE and BuChE tetramers, besides amphiphilic dimers (G(2)(A)) and monomers (G(1)(A)) were identified in SAMR1 brain and their distribution was little modified in SAMP8 brain. Blood plasma does not seem to provide the excess of BuChE activity in SAMP8 brain; it probably arises from glial cell changes owing to astrocytosis.     

Effects of age on plasma levels of calcium-regulating hormones and bone status in male SAMP8 mice

This study was undertaken to examine whether the plasma levels of calcium-regulating hormones and bone status alter with age in male senescence accelerated mice (SAM), SAMP8. Age-matched senescence-resistant mice, SAMR1, were used as controls. The blood and femur samples were collected at 2.5 months of age (M) and then monthly from 3 to 12 M for physicochemical analyses, biochemical analyses, and the determination of hormones by radioimmunoassay. With advancing age, the plasma calcitonin (CT) levels decreased progressively, and the plasma parathyroid hormone (PTH) and 1,25-dihydroxycholecalciferol (1,25(OH)2D3) levels increased in both SAMR1 and SAMP8. The plasma calcium concentrations were maintained within a narrow range throughout the experimental period, while the plasma phosphorus (P) concentrations decreased with age in both strains. In contrast to SAMR1, the curves of age-related changes in the plasma CT levels and P concentrations were lower, and those in the plasma PTH levels were higher in SAMP8. The femoral bone densities and calcium contents increased gradually with age from the beginning of the experiment and peaked at 6 M in both strains, then declined. Those peaks were lower in SAMP8 than in SAMR1. These results indicate that the male SAMP8 develops osteoporotic signs earlier than SAMR1, and is proved to be a satisfactory animal model for longitudinal studies related to osteoporosis for men.     

Adiposity-Related Biochemical Phenotype in Senescence-Accelerated Mouse Prone 6 (SAMP6)

Senescence-accelerated mouse prone 6 (SAMP6) is a model of senile osteoporosis. From 10 to 22 wk of age, SAMP6 mice were heavier than age-matched AKR/J and SAMR1 mice. Body mass indices of 10- and 25-wk-old SAMP6 mice were higher than those of age-matched AKR/J and SAMR1 mice, indicating obesity in the SAMP6 animals. We compared the blood biochemical values among SAMP6, SAMR1, and AKR/J mice to assess whether the SAMP6 strain has abnormal obesity-related parameters. Plasma glucose, triglyceride, insulin, and leptin levels were higher in 10-wk-old SAMP6 mice than in age-matched SAMR1 and AKR/J mice, whereas plasma glucagon and adiponectin levels in 25-wk-old SAMP6 were lower compared with those in age-matched SAMR1 and AKR/J. Total cholesterol levels in SAMR1 and SAMP6 mice at 10 and 25 wk of age were higher than those in AKR/J mice. Hepatic lipid levels were higher in 10- and 25-wk-old SAMP6 mice compared with age-matched AKR/J and SAMR1 animals. These results indicate that SAMP6 mice exhibit obesity and hyperlipidemia, suggesting that the SAMP6 strain is a potential tool for the study of hyperlipidemia.Abbreviations: BMI, body mass indexThe senescence-accelerated mouse strains were developed through selective breeding of AKR/J mice based on graded scores for senescence and pathologic phenotypes.⁴⁴ The 9 senescence-prone (SAMP) strains all have a shortened lifespan and display an early onset of senescence after normal development and maturation, whereas the 3 senescence-resistant (SAMR) strains are resistant to early senescence and serve as controls. Among the SAMP strains, SAMP8 and SAMP10 exhibit deficits in learning and memory at a relatively early stage in their lifespan.^6,30 In contrast, SAMP6 mice are considered to be a model of senile osteoporosis, with their low bone mass and slow bone loss;²⁴ the bone mineral density of SAMP6 mice decreases after 4 mo of age.^14,17Our regular measurement of body weight revealed that SAMP6 mice were significantly higher between 10 and 22 wk of age than were age-matched SAMR1 and AKR/J. Based on this observation, we decided to compare body mass indices (BMIs), blood biochemical values, and liver sections among mice of these strains at 10 and 25 wk of age, which respectively correspond to the beginning and end of a period of significant body weight gain in SAMP6 mice compared with age-matched SAMR1 and AKR/J. Increased BMIs of SAMP6 mice at 10- and 25 wk compared with those of age-matched AKR/J and SAMR1 animals would indicate obesity in the SAMP6. In addition, because osteoblasts and adipocytes are thought to share a common precursor cell, osteoporosis and enhanced adipogenesis may be related. For example, adipogenesis in the bone marrow increases with aging and during osteoporosis,^15,33,34 and increased bone turnover occurs in hypercholesterolemic or dyslipidemic patients.²² Therefore obesity in SAMP6 mice might be due at least in part to enhanced adipogenesis. We measured and compared blood biochemical values among SAMP6, SAMR1, and AKR/J (the founder for the SAM strains) mice to assess whether the SAMP6 strain has abnormalities in blood biochemical markers, such as triglycerides or cholesterol.     

Genetic typing of the Senescence-Accelerated Mouse (SAM) strains with microsatellite markers

The Senescence-Accelerated Mouse (SAM) strains constitute a murine model of accelerated senescence originating from the ancestral AKR/J strains and consist of nine senescence-prone (SAMP) strains and four senescence-resistant (SAMR) strains. The chromosomes (Chrs) of the SAM strains were typed with 581 microsatellite markers amplified by PCR, and the fundamental genetic information of the SAM strains was obtained. One-third of the examined markers displayed polymorphism among the strains, and only two alleles were detected in almost all loci among the SAM and AKR/J strains. However, in 12 loci (5.6% of total 215 polymorphic markers), the third allele was detected among the SAM strains. The genetic typing and developmental history suggested that the SAM strains were related inbred strains developed by the accidental crossing between the AKR/J strain and other unknown strain(s). Comparison of the distribution of the loci in the SAMP and the SAMR series revealed notable differences in the four regions on Chrs 4, 14, 16, and 17. This indicated that some of these chromosomal sites might contain the genes responsible for accelerated senescence in the SAMP series. Received: 17 July 1998 / Accepted: 17 November 1998     

Ultrastructural changes in bones of the senescence-accelerated mouse (SAMP6): a murine model for senile osteoporosis

SAMP6, a substrain of senescence-accelerated mice, was developed as an animal model for senile osteoporosis. In the present study, we investigated the bone morphology, together with serum calcium and bone mineral density (BMD) in SAMP6 and age-matched normal mice SAMR1. We did not find any significant differences between SAMR1 and SAMP6 at 1 month of age with regard to the serum compositions and bone morphology. As compared with SAMR1, BMD, the femoral weight, femoral calcium and phosphorus levels were significantly reduced in SAMP6 at 2 and 5 months of age. The number of osteoblasts in trabecular bones was also significantly reduced. Swollen mitochondria and myelin-like structures were found in osteoblasts and osteocytes of SAMP6 mice at 2 and 5 months of age. There was a greater proportion of resting surface and less forming surface in the femoral endosteal surfaces of SAMP6 mice. The amount of trabecular bone in the lumbar vertebra and the distal metaphysis of the femur was reduced. The number of the mast cells in bone marrow of the tibia significantly increased in SAMP6 mice. These findings indicate that the lower bone mass in SAMP6 was due to the reduction in osteoblast formation and suggested that mast cells in bone marrows play a role in the pathogenesis of senile osteoporosis.     

Identification of differentially expressed genes in senescence-accelerated mouse testes by suppression subtractive hybridization analysis

Senescence-accelerated mouse (SAM) strains constitute a model of accelerated senescence coupled with a short lifespan and the early development of various age-related disorders. To identify differential gene expression in testes between senescence-accelerated SAMP1 and control SAMR1 mice, we performed suppression subtractive hybridization. We observed that the expression of three genes related to cell proliferation (myosin regulatory light chain B, aldolase 1A isoform, and cytochrome c oxidase subunit VIc) were upregulated and four genes implicated in spermatogenesis were downregulated in SAMP1 mice. Asb-8, a member of ankyrin repeat-containing proteins, was abundantly expressed in the testes and downregulated in SAMP1. The other three downregulated genes (germ cell-specific gene 1, T-complex polypeptide 1b, and activator of cAMP responsive element modulator in testis) have been reported to regulate late-stage spermatogenesis. These gene expression profiles might explain the findings of early testicular maturation and rapid decline in the ability to produce spermatozoa with advancing age in SAMP1 mice.