Takatoshi Matsushita

Pathobiology of the senescence-accelerated mouse (SAM)

Routine postmortem examinations and the pathobiological features revealed by systematically designed studies have shown several pathologic phenotypes that are often characteristic enough to differentiate among the various SAM strains: senile amyloidosis in SAMP1, -P2, -P7, -P9, -P10, and -P11; secondary amyloidosis in SAMP2 and -P6; contracted kidney in SAMP1, -P2, -P10, and -P11; immunoblastic lymphoma in SAMR1 and -R4; histiocytic sarcoma in SAMR1 and -R4; ovarian cysts in SAMR1; impaired immune response in SAMP1, -P2, and -P8; hyperinflation of the lungs in SAMP1; hearing impairment in SAMP1; degenerative temporomandibular joint disease in SAMP3; senile osteoporosis in SAMP6; deficits in learning and memory in SAMP8 and -P10; emotional disorders in SAMP8 and -P10; cataracts in SAMP9; and brain atrophy in SAMP10. These are all age-associated pathologies, the incidence and severity of which increase with advancing age. The SAM model in which these pathobiological features have been carefully monitored will be a valuable tool in the clarification of the pathogenic mechanisms of age-associated pathologies and in the research for effective methods to modulate or ameliorate these pathologies.

Spontaneous Spongy Degeneration of the Brain Stem in SAM-P/8 Mice, a Newly Developed Memory-Deficient Strain

Abstract. A spontaneous spongy degeneration of the brain stem and spinal cord was discovered in a murine model of accelerated senescence (SAM), cared for under both conventional (SAM-P/8) and specific pathogen-free (SAM-P/8/Ta) conditions. SAM-P/8 and SAM-P/8/Ta showed no clinical neurological abnormalities, yet there was a deterioration in learning and memory abilities. Light microscopic examination revealed a spongy degeneration in the brain stem and spinal cord, in the reticular formation, and proliferation of hypertrophic astrocytes in the spongy area. The spongiform degeneration progressed with advancing age from four to eight months, after which the entire brain was involved. Astrocytosis increased with advancing degeneration. Ultrastructurally, mild dendritic swelling occurred at one month of age. At two months of age, moderate postsynaptic swelling and a widening of intracellular membrane structure were observed, and at age five months there were large vacuoles circumscribed by membranous lamellae, identifiable as myelin. Vacuoles in SAMP/ 8 proved to be swollen neuronal processes and oligodendroglial processes. These SAM-P/8 and SAM-P/8/Ta strains of mice are new memory-deficient strains with spontaneous spongy degeneration associated with aging.

Transmission of mouse senile amyloidosis

In mouse senile amyloidosis, apolipoprotein A-II polymerizes into amyloid fibrils (AApoAII) and deposits systemically. Peripheral injection of AApoAII fibrils into young mice induces systemic amyloidosis (Higuchi et al, 1998). We isolated AApoAII amyloid fibrils from the livers of old R1.P1-Apoa2c mice and injected them with feeding needles into the stomachs of young R1.P1-Apoa2c mice for 5 consecutive days. After 2 months, all mice had AApoAII deposits in the lamina propria of the small intestine. Amyloid deposition extended to the tongue, stomach, heart, and liver at 3 and 4 months after feeding. AApoAII suspended in drinking water also induced amyloidosis. Amyloid deposition was induced in young mice reared in the same cage for 3 months with old mice who had severe amyloidosis. Detection of AApoAII in feces of old mice and induction of amyloidosis by the injection of an amyloid fraction of feces suggested the propagation of amyloidosis by eating feces. Here, we substantiate the transmissibility of AApoAII amyloidosis and present a possible pathogenesis of amyloidosis, ie, oral transmission of amyloid fibril conformation, where we assert that exogenous amyloid fibrils act as templates and change the conformation of endogenous amyloid protein to polymerize into amyloid fibrils.

MANAGEMENT AND DESIGN OF THE MAINTENANCE OF SAM MOUSE STRAINS : AN ANIMAL MODEL FOR ACCELERATED SENESCENCE AND AGE-ASSOCIATED DISORDERS

The Senescence-Accelerated Mouse (SAM) was established by inbreeding and pedigree selection based on the life span, degree of senescence, as well as the incidence and degree of several age-associated disorders. At first, SAM strains were developed under conventional conditions, but now some strains are also maintained under specific pathogen-free conditions. There are many methods used to maintain such strains of mice; our methods will be introduced as one example of how to develop and maintain strains of mice used in aging research.

Acceleration of chromosome aberrations in senescence-accelerated strains of mice.

Age-related changes in the frequency of chromosome aberrations were examined using bone marrow cells of senescence-accelerated strains of mice (SAM). An accelerated senescence-prone strain, SAM-P/1, showed a striking increase in the frequency of chromosome aberrations, from age 3 to 8 months, whereas an accelerated senescence-resistant strain, SAM-R/1, at the same ages showed only a slight increase. Both these strains were derived from the same ancestral strain (AKR/J). The rate of increase of chromosome aberration frequency paralleled the advancement of senescence in both strains. These observations suggest that there are genetic factors which closely relate to chromosomal instability and acceleration of the senescence processes.

Induction of AApoAII amyloidosis by various heterogeneous amyloid fibrils

Preformed amyloid fibrils accelerate conformational changes of amyloid precursor proteins and result in rapid extension of amyloid fibrils in vitro. We injected various kinds of amyloid fibrils into mice with amyloidogenic apoAII gene (Apoa2C ). The most severe amyloid depositions were detected in the tissues of mice injected with mouse AApoAII(C) amyloid fibrils. Mild amyloid depositions were also detected in the tissues of mice that were injected with other types of fibrils, including synthetic peptides and recombinant proteins. However, no amyloid depositions were found in mice that were injected with non‐amyloid fibril proteins. These results demonstrated that a common structure of amyloid fibrils could serve as a seed for amyloid fibril formation in vivo.

Induction of Protein Conformational Change in Mouse Senile Amyloidosis

Aggregated amyloid fibrils can induce further polymerization of precursor proteins in vitro, thus providing a possible basis for propagation or transmission in the pathogenesis of amyloidoses. Previously, we postulated that the transmission of amyloid fibrils induces conformational changes of endogenous amyloid protein in mouse senile amyloidosis (Xing, Y., Nakamura, A., Chiba, T., Kogishi, K., Matsushita, T., Fu, L., Guo Z., Hosokawa, M., Mori, M., and Higuchi, K. (2001) Lab. Invest.81, 493–499). To further characterize this transmissibility, we injected amyloid fibrils (AApoAII(C)) of amyloidogenic C type apolipoprotein A-II (APOAIIC) intravenously into 2-month-old SAMR1 mice, which have B type apolipoprotein A-II (APOAIIB), and develop few if any amyloid deposits spontaneously. 10 months after amyloid injection, deposits were detected in the tongue, stomach, intestine, lungs, heart, liver, and kidneys. The intensity of deposition increased thereafter, whereas no amyloid was detected in distilled water-injected SAMR1 mice, even after 20 months. The deposited amyloid was composed of endogenous APOAIIB with a different amyloid fibril conformation. The injection of these amyloid fibrils of APOAIIB (AApoAII(B)) induced earlier and more severe amyloidosis in SAMR1 mice than the injection of AApoAII(C) amyloid fibrils. Thus, AApoAII(C) from amyloidogenic mice could induce a conformational change of less amyloidogenic APOAIIB to a different amyloid fibril structure, which could also induce amyloidosis in the less amyloidogenic strain. These results provide important insights into the pathogenesis of amyloid diseases.

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

Abstract. 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.

Tubular aggregates in the skeletal muscle of the senescence-accelerated mouse; SAM.

We investigated the skeletal muscles of nine strains of senescence accelerated mouse (SAM), DDD, AKR/J, C57BL/6J, A/J and BALB/c mice. We found that male SAMP8, SAMP7, C57BL/6J, A/J and BALB/c mice expressed tubular aggregates (TAs) in their skeletal muscle. Among these strains, the SAMP8 strain, which exhibits a short life span and various age-associated neurodegenerative disorders plus mitochondrial dysfunction, showed TAs more markedly than the others. Thus, we compared SAMP8 mice against SAMR1 mice, an accelerated senescence-resistant strain. Light- and electron micrographs showed that male SAMP8 mice exhibited an age-dependent aggravation of TA accumulation. There were no significant differences in the serum lactate/pyruvate levels between the SAMP8 and SAMR1 mice. However, the serum creatine kinase (CK) levels of the 3 and 6-month-old SAMP8 mice were higher than that of the corresponding SAMR1 mice. Considering the serum CK levels and the mitochondrial dysfunction of SAMP8 mice, we conclude that the TAs may be involved in the homeostasis of energy metabolism that is not appropriately regulated in the SAMP8 mouse mitochondrion.

Effects of aging and blood pressure on the structure of the thoracic aorta in SAM mice: a model of age-associated degenerative vascular changes

The effects of aging and blood pressure on the structural alterations of the thoracic aorta were examined using male, accelerated senescence-prone, short-lived SAMP11 mice or accelerated senescence-resistant, long-lived SAMR1 mice. The aortic wall thickness increased significantly by 34% in SAMR1 and by 62% in SAMP11 with advanced age. We observed branching, breakage and disorganization of the elastic lamellae, an increase in thin collagen fibrils between the medial smooth muscle cells and hypertrophy but a significant decrease in the number of medial smooth muscle cells with aging in both strains. These alterations observed in SAMP11 occurred earlier and were more exaggerated with advanced age than in SAMR1. The aortic lumen dilated gradually in SAMR1, but narrowed significantly in SAMP11 with aging. The systolic blood pressure did not differ significantly among SAMP11s aged 3-9months, or among all ages of SAMR1. However, it was elevated in SAMP11 at the terminal stage of their life. Our results suggest that the aorta in SAMR1 might reflect the physiological process of aging, whereas SAMP11 showed earlier changes due to the senescence acceleration of the vascular cells, which were exaggerated by the elevated blood pressure.