Polyamines modulate phosphorylation and acetylation of non-histone chromosomal proteins of the cerebral cortex of rats of various ages

Mechanisms of spermidine-induced autophagy and geroprotection

Aging involves the systemic deterioration of all known cell types in most eukaryotes. Several recently discovered compounds that extend the healthspan and lifespan of model organisms decelerate pathways that govern the aging process. Among these geroprotectors, spermidine, a natural polyamine ubiquitously found in organisms from all kingdoms, prolongs the lifespan of fungi, nematodes, insects and rodents. In mice, it also postpones the manifestation of various age-associated disorders such as cardiovascular disease and neurodegeneration. The specific features of spermidine, including its presence in common food items, make it an interesting candidate for translational aging research. Here, we review novel insights into the geroprotective mode of action of spermidine at the molecular level, as we discuss strategies for elucidating its clinical potential.

New Insights into the Roles and Mechanisms of Spermidine in Aging and Age-Related Diseases

High incidences of morbidity and mortality associated with age-related diseases among the elderly population are a socio-economic challenge. Aging is an irreversible and inevitable process that is a risk factor for pathological progression of diverse age-related diseases. Spermidine, a natural polyamine, plays a critical role in molecular and cellular interactions involved in various physiological and functional processes. Spermidine has been shown to modulate aging, suppress the occurrence and severity of age-related diseases, and prolong lifespan. However, the precise mechanisms through which spermidine exerts its anti-aging effects have not been established. In this review, we elucidate on the mechanisms and roles underlying the beneficial effects of spermidine in aging from a molecular and cellular perspective. Moreover, we provide new insights into the promising potential diagnostic and therapeutic applications of spermidine in aging and age-related diseases.

Age-dependent changes in the phosphorylation of nuclear proteins of submandibular glands in isoproterenol-treated rats

Age-dependent changes in the regulation of the phosphorylation of nuclear proteins were investigated in relation to DNA synthesis in rat submandibular glands after injection of isoproterenol (IPR). The level of phosphorylation of nuclear proteins in the tissue increased rapidly after birth, reaching a maximum at 4 weeks, and then decreased to the level of 52-week-old rats. The level of protein kinase activity in nuclei varied in parallel with that of phosphorylation of nuclear non-histone proteins after birth. The time after the injection of IPR required to initiate the phosphorylation of nuclear non-histone proteins of rat submandibular glands, which occurs prior to the onset of RNA synthesis that precedes the replication of DNA, increased with age. These results suggest that this delayed onset of phosphorylation plays a regulatory role in cell proliferation and cell function during aging.

In vitro acetylation of the liver HMG non-histone proteins and its modulation by spermine and dexamethasone during aging of rats

The in vitro acetylation of HMG proteins was studied using liver slices of young (18-week) and old (138-week) male rats. Acetylation of total HMG proteins is lower in old age. The incorporation of (14C) acetate into individual HMG proteins varies remarkably with advancing age. Whereas acetylation of high mol. wt. proteins (HMG 1 and 2) is higher, that of low mol. wt. proteins (HMG 14 and 17) is lower in the liver of young rats as compared to the old ones. Spermine stimulates the acetylation of HMG 1 and 14 in young and HMG 1, 2 and 14 in old age. It inhibits the acetylation of HMG 17 in both ages. Dexamethasone decreases the level of incorporation of (14C) into HMG 1 and 17 in young and HMG 14 and 17 in old rats. On the other hand, it stimulates the acetylation of HMG 14 by two-fold in young and that of HMG 1 and 2 by more than three-fold in old rats. Such alteration in the acetylation of HMG proteins may account for age-related changes in the structure and function of chromatin.

Age changes of chromatin. A review

The age-related studies of chromatin and DNA has attracted significant interest in recent years. However, individual works describe only some and a few of the many changes of chromatin. It is often difficult to decide whether these changes have secondary or primary nature. The overview of these studies makes it possible to realize how many very complex and interdependent changes occur in chromatin during ageing. Chromatin is the most complex among self-reproducible parts of the cell. A very sophisticated structure of chromatin makes possible the differential transcription of a genetic programme which supports the accurate specialized functions of each cell in interphase and also provides a mechanism for perfect reproduction of this complex machinery of genetic information during cell division. It is known that chromatin proteins, more than chromatin DNA show tissue specificity and developmental changes. There are many theories of cellular ageing which select some special types of DNA, RNA or protein changes and to promote them as the main or primary causes of cellular senescence. However, if these changes are considered within the more comprehensive picture of functional structure of chromatin the results show the interdependence of individual alterations and their proper place in the complex, multichannel, species and tissue-specific character of actual ageing. An attempt to summarize the basic facts and theories about age changes of the two main parts of chromatin structure, proteins and DNA is being made in this review. At the same time the author tried to develop a concept of non-random distribution of the age changes in chromatin and a possible higher rate of accumulation of different alteration and lesions in the transcribed and functionally active parts of chromatin.