Zinc improves the development of human CD34+ cell progenitors towards NK cells and increases the expression of GATA-3 transcription factor in young and old ages.

Aim of this study was to evaluate the effect of zinc on the kinetic of development of CD34(+) cell progenitors towards NK cells in young and old ages. CD34(+) cells were purified from peripheral blood of healthy subjects and cultured in medium supplemented with interleukin-15, interleukin-7, Flt 3 ligand, and stem cell factor. The number of cells developed in culture was significantly lower in old than in young subjects. CD34(+) cells progressively lost CD34 antigen with a faster kinetics in old than in young donors. The percentage of primitive double positive CD34(+)CD133(+) cells inside the purified CD34(+) cells was greatly lower in old than in young subjects. These cells progressively decreased in cultures from young subjects whereas they remained at very low levels in old donors. Cells developed in culture acquired a NK phenotype mainly characterized by CD56(+)CD16(-) cells in young subjects and CD56(-)CD16(+) cells in old donors. These NK cells exerted a lower cytotoxic activity in old than in young subjects. The supplementation with zinc greatly increased the number of cells in culture and the percentage and the cytotoxic activity of NK cells both in young and old ages. In zinc supplemented cultures, a 3.6-fold and a 4.1-fold increased expression of GATA-3 transcription factor was observed in young and old donors, respectively. Our data demonstrate that zinc influences the proliferation and differentiation of CD34(+) progenitors both in young and old ages.

Zinc improves the development of human CD34+ cell progenitors towards Natural Killer cells and induces the expression of GATA-3 transcription factor.

The Natural Killer cell maturation from CD34(+) hematopoietic cell precursors is a complex process that requires the synergistic effect of different cytokines and growth factors. Although there have been a number of important advances in our understanding of the Natural Killer differentiation, the developmental step leading to mature Natural Killer cells is still poorly defined. We evaluated the effect of two zinc concentrations (10 and 20microM) on the kinetic of development of CD34(+) cell progenitors towards Natural Killer cells. CD34(+) cells were purified from peripheral blood and cultured in medium supplemented with interleukin-15, interleukin-7, Flt 3 ligand, and stem cell factor. CD34(+) cells underwent proliferation and progressively lost CD34 antigen and acquired a CD56(+) phenotype. These CD56(+) cells exerted cytotoxic activity and expressed the CD94 inhibitory receptor. The supplementation with zinc greatly increased both the number of cells in culture and the absolute number of CD56(+) cells. Zinc induced higher levels of cytotoxic activity and a higher number of perforin-producing and of CD94-bearing CD56(+) cells in comparison with zinc unsupplemented cultures in early stages of Natural Killer cell development. The zinc-induced changes in CD34-derived CD56(+) cells were associated with an increased expression of GATA-3, a zinc-finger transcription factor providing for maturation and activity of T and Natural Killer cells. The increase was related to a higher CD56(+) cell number (10microM zinc), or to an increased GATA-3 mRNA transcription in CD56(+) cells (20microM zinc). Our data demonstrate that zinc influences the proliferation and differentiation of CD34(+) progenitors.

The G/C915 polymorphism of transforming growth factor beta1 is associated with human longevity: a study in Italian centenarians.

Sequence variations in a variety of pro- or anti-inflammatory cytokine genes have been found to influence successful aging and longevity. Because of the role played by the transforming growth factor beta1 (TGF-beta1) cytokine in inflammation and regulation of immune responses, the variability of the TGF-beta1 gene may affect longevity by playing a role in inflamm-aging. Two polymorphisms, G/A -800 and C/T -509, located in the 5' region, and two missense polymorphisms, T/C 869 and G/C 915 which change (Leu > Pro)10 and (Arg > Pro)25, respectively, located in the signal peptide, were analysed in 419 subjects from Northern and Central Italy, including 172 centenarians and 247 younger controls. In addition, the effects of the TGF-beta1 genetic variability on plasma levels of the biologically active form (naturally processed) of this cytokine were studied in 143 randomly selected subjects, including 73 centenarians. Significant differences were found at the +915 site as far as the C allele and GC genotype were concerned, both of them being lower in centenarians than in young controls (P=0.034 and 0.028, respectively), but none of the other tested genetic variants was significantly different between centenarians and controls. Moreover, a particular haplotype combination (G -800/C -509/C 869/C 915) was notably lower in centenarians than in younger individuals (P=0.007). Finally, active TGF-beta1 plasma levels were significantly increased in the elderly group, but no relationship with TGF-beta1 genotypes was observed. These results suggest that, at least in this population, the variability of the TGF-beta1 gene influences longevity and that the age-related increase in plasma levels of active TGF-beta1 seems not to be genetically regulated.

Molecular variation of human HSP90alpha and HSP90beta genes in Caucasians.

Understanding DNA variation within the human genome is fundamental to the identification and interpretation of genetic components underlying complex traits and diseases. Despite their role in many crucial cellular pathways and their reported involvement in many complex diseases no data are available on the molecular variability of the genes coding for Heat Shock Proteins 90Kda (HSP90). Towards this purpose we have used DHPLC methodology to survey, a sample of Caucasians for genetic polymorphisms in the exons and exon-flanking regions of the expressed genes of human HSP90 gene families, HSP90alpha (HSPCAL4, 14q31.3) and HSP90beta (HSPCB, 6p12). A total of 18 and 11 variants were found in the HSP90-alpha and -beta genes respectively, providing an initial view of human genetic variation in these important genes. Only three of the observed mutations altered the genic product. Interestingly, one of the variations observed was a missense mutation leading to the impairment of the hsp90alpha protein.

Metallothioneins (I+II) and thyroid-thymus axis efficiency in old mice: role of corticosterone and zinc supply.

Thymic atrophy or thymus absence causes depressed thyroid-thymus axis (TTA) efficiency in old, young propyl-thiouracil (PTU) (experimental hypothyroidism) and in young-adult thymectomised (Tx) mice, respectively. Altered zinc turnover may be also involved in depressed TTA efficiency. Zinc turnover is under the control of zinc-bound metallothioneins (Zn-MTs) synthesis. Thyroid hormones, corticosterone and nutritional zinc affect Zn-MT induction. Zn-MT releases zinc in young-adult age during transient oxidative stress for prompt immune response. In constant oxidative stress (ageing and liver regeneration after partial hepatectomy), high liver Zn-MTs, low zinc ion bioavailability and depressed TTA efficiency appear. This last finding suggested that MT might not release zinc during constant oxidative stress leading to impaired TTA efficiency. The aim of this work/study is to clarify the role of Zn-MTs (I+II) in TTA efficiency during development and ageing. The main results are (1) Old and PTU mice display high corticosterone, enhanced liver MTmRNA, low zinc and depressed TTA efficiency restored by zinc supply. Increased survival and no significant increments in basal liver Zn-MTs proteins occur in old and PTU mice after zinc supply. (2) Lot of zinc ions bound with MT in the liver from old mice than young (HPLC). (3) Young-adult Tx mice, evaluated at 15 days from thymectomy, display high MTmRNA and nutritional-endocrine-immune damage restored by zinc supply or by thymus grafts from old zinc-treated mice. (4) Young-adult Tx mice, but evaluated at 40 days from thymectomy, display natural normalisation in MTmRNA and nutritional-endocrine-immune profile with survival similar to normal mice. (5) Stressed (constant dark for 10 days) mice overexpressing MT display low zinc, depressed immunity, reduced thymic cortex, high corticosterone, altered thyroid hormones turnover showing a likeness with old mice. These findings, taken altogether, show that corticosterone is pivotal in MTs induction under stress. MTs bind preferentially zinc ions in constant oxidative stress, but with no release of zinc from MT leading to impaired TTA efficiency. Zinc supply restores the defect because zinc has no interference in affecting pre-existing Zn-MTs protein concentrations in old and PTU mice. Therefore, free zinc ions are available for TTA efficiency after zinc supply. Thymus from old zinc-treated mice induces the same restoring effect when transplanted in Tx recipients. However, Tx mice display natural normalisation in MTmRNA and in nutritional-endocrine-immune profile in the long run. Therefore, Zn-MTs (I+II) are crucial in zinc homeostasis for endocrine-immune efficiency during the entire life assuming a role of potential and novel 'biological clock of ageing'.

The role of IL-1 gene cluster in longevity: a study in Italian population.

In this study, we analysed the polymorphic variants of IL-1alpha (C-T transition at position -889), IL-1beta (C-T transition at position -511) and IL-1 receptor antagonist (Ra) (86-bp repeated sequence in intron 2) in 1131 subjects (453 females and 678 males) from Northern and Central Italy, including 134 centenarians, to evaluate whether IL-1 cluster alleles might be differently represented in people selected for longevity. In addition, IL-1Ra and IL-1beta plasma levels were quantified by ELISA in 130 randomly selected subjects. No significant differences in the genotype and allele frequency distributions were observed between young, elderly and centenarian subjects. IL-1Ra plasma levels showed an age-related increase, whereas IL-1beta plasma levels did not show any detectable age-related trend. Neither IL-1Ra nor IL-1beta plasma levels showed any relationship with genotypes of the three IL-1 genes. These results suggest that no one particular polymorphism in the IL-1 gene cluster yields an advantage for survival in the last decades of life, and that the age-related increase in plasma levels of IL-1Ra seems not to be genetically regulated but a likely safeguard mechanism to buffer the age-associated increased inflammatory state.

In vitro IL-6 production by EBV-immortalized B lymphocytes from young and elderly people genotyped for -174 C/G polymorphism in IL-6 gene: a model to study the genetic basis of inflamm-aging.

In the present investigation we analysed Interleukin 6 (IL-6) in vitro production by Epstein-Barr virus (EBV)-immortalized B lymphocytes established from 43 subjects, 15 young people and 28 elderly people, including 18 centenarians, after 3, 6, 9, 24, 48 and 72 h of culture. The subjects were genotypized for the C to G transition at nucleotide -174 of IL-6 gene promoter (-174 C/G) and were classified as C allele carriers (C+) and non-carriers (C-). We found that: (i) the interindividual difference in in vitro IL-6 production was wider in elderly individuals in respect to young individuals, leading to different coefficient of variation in the two groups; (ii) the -174 C/G polymorphism had an age-related effect on IL-6 in vitro production. Only among C- people, cells from elderly subjects produced significant higher level of IL-6 than cells from young subjects. These data are consistent with our previous results regarding the IL-6 serum levels in a large group of people of different age, including centenarians. Thus, the EBV-immortalized B lymphocytes can be considered a useful in vitro model for studying the genetic control of IL-6 production and its changes with age.

The -174 C/G locus affects in vitro/in vivo IL-6 production during aging.

IL-6 in vitro production, as well as the serum/plasma concentration of the cytokine, increase with age. In the present investigation, a total of 62 individuals (31 males and 31 females), aged from 29 to 93 years of age (mean age of males: 60.4 years; mean age of females: 59.4 years) were assessed for IL-6 plasma concentration, and for IL-6 in vitro production, using supernatants of 4h cultured adherent peripheral blood mononuclear cells (aPBMC). The subjects were examined for a C to G transition at nucleotide -174 of the IL-6 gene promoter (-174 C/G locus), and were classified as C allele carriers (C+) or non-carriers (C-). We found that: (i) aPBMC from C+ individuals produced smaller amounts of IL-6 in vitro than C- individuals; (ii) IL-6 production by aPBMC increased with age in C+ but not in C- subjects; (iii) there was no correlation between IL-6 plasma levels and in vitro IL-6 production by aPBMC; (iv) IL-6 C+ individuals had lower plasma levels than C- individuals, and this phenomenon was significant only in men. On the whole our data indicate that the production of IL-6 is genetically controlled and age- and gender-dependent.

MtmRNA gene expression, via IL-6 and glucocorticoids, as potential genetic marker of immunosenescence: lessons from very old mice and humans.

Metallothioneins (MTs) are involved in metal-related cell homeostasis because of their high affinity for metals forming clusters. The main functional role of MTs is to sequester and/or dispense zinc participating in zinc homeostasis, which is relevant in normal immune response. Consistent with this role, MTs gene expression (MTmRNA) is transcriptionally induced by a variety of stressing agents to protect cells from reactive oxygen species. In order to accomplish this task, MTs gene expression is affected by glucocorticoids and IL-6 for a prompt immune response. This protection is peculiar in young-adult age during transient stress and inflammatory condition, but not in ageing because stress-like condition and inflammation are constant for the whole circadian cycle. This may lead MTs to turn-off from role of protection in young age to deleterious one in ageing. The aim is to suggest MTmRNA as potential genetic marker of immunosenescence. Liver MTmRNA, IL-6 and glucocorticoids levels are high, whereas the bioavailability of zinc ions is low and natural killer cells activity is depressed in old and very old mice during the light period as compared to young in the same period. An inversion of nutritional-endocrine-immune profile exclusively occurs in young mice during the night showing the existence of immune plasticity. No inversion occurs in old mice during the night. As a consequence, no immune plasticity in old mice ensues. By contrast, very old mice remodel the altered MTmRNA and immune-endocrine profile during the night up to values of young ones observed during the light period. Therefore, the remodelling of MTmRNA may be involved in the maintenance of immune plasticity with subsequent successful ageing. Thus, MTmRNA, via IL-6 and glucocorticoids, may be potential genetic marker of immunosenescence. This assumption is reinforced by low MTmRNA in lymphocytes of nonagenarians and young-adult people in comparison with elderly and Down's syndrome subjects.

Age- and gender-related alterations of the number and clonogenic capacity of circulating CD34+ progenitor cells.

The aim of this study was to evaluate the peripheral representation and the clonogenic capacity of CD34(+) progenitor cells from 130 healthy subjects (80 females and 50 males) ranging in age from 16 to 100 years. We demonstrated that the absolute number of circulating CD34(+) cells progressively and significantly decreased with advancing age, with a 2-fold reduction in subjects aged more than 80 years. The number of granulocyte-macrophagic (CFU-GM), erytroid (BFU-E), and mixed (CFU-GEMM) colonies which developed from the number of CD34(+) purified cells per ml, progressively and significantly decreased with advancing age. The reduction of both CD34(+) cell number and clonogenic capacity during aging was statistically significant in males but not in females. When evaluated on a per cell bases, a significant age-related decrease in the number of CFU-GM colonies was observed in female but not in male subjects. Our study demonstrates the influence of gender on age-related alterations of the number and clonogenic capacity of CD34(+) cells in the peripheral blood. This evidence deserves particular consideration for the future planning of stem cell therapy in age-associated debilitating diseases.