Determinants of uterine aging: lessons from rodent models

The uterus is an indispensable organ for the development of a new life in eutherian mammals. The female mammalian reproductive capacity diminishes with age. In this respect, the senescence of uterine endometrium is convinced to contribute to this failure. This review focuses on the physiological function of the uterus and the related influence of aging mainly in rodent models. A better understanding of the underlying mechanisms governing the process of uterine aging is hoped to generate new strategies to prolong the reproductive lifespan in humans.     

Cancer,aging and immunotherapy: lessons learned from animal models

Aging of the immune system is associated with a dramatic reduction in responsiveness as well as functional dysregulation. This deterioration of immune function with advancing age is associated with an increased incidence of cancer. Although there is a plethora of reports evaluating the effect of immunotherapy in stimulating antitumor immune responses, the majority of these studies do not pay attention to the effect aging has on the immune system. Studies from our group and others indicate that immunotherapies could be effective in the young, are not necessarily effective in the old. To optimally stimulate an antitumor immune response in the old, it is necessary to (1) identify and understand the intrinsic defects of the old immune system and (2) use relevant models that closely reflect those of cancer patients, where self-tolerance and aging are present simultaneously. The present review summarizes some defects found in the old immune system affecting the activation of antitumor immune responses, the strategies used to activate stronger antitumor immune response in the old and the use of a tolerant animal tumor model to target a self-tumor antigen for the optimization of immunotherapeutic interventions in the old.     

Autophagy and aging: new lessons from progeroid mice

It is widely-assumed that the autophagic activity of living cells decreases with age and probably contributes to the accumulation of damaged macromolecules and organelles during aging. Over the last few years, the study of segmental progeroid syndromes in which certain aspects of aging are manifested precociously or in exacerbated form, has increased our knowledge of the molecular basis of aging. We have recently reported the unexpected finding that distinct progeroid murine models exhibit an extensive basal activation of autophagy instead of the characteristic decline in this process occurring during normal aging. Further studies on Zmpste24-null progeroid mice, which are a reliable model of human Hutchinson-Gilford progeria, have revealed that the observed autophagic increase is associated with a series of metabolic alterations resembling those occurring under calorie restriction or in other situations reported to prolong lifespan. Here, we analyze these unexpected findings and discuss their possible implications for the development of premature aging.     

Oxidative stress and aging: Learning from yeast lessons

The yeast Saccharomyces cerevisiae has played a vital role in the understanding of the molecular basis of aging and the relationship of aging process with oxidative stress (non-homeostatic accumulation of Reactive Oxygen Species, ROS). The mammalian and yeast antioxidant responses are similar and over 25 % of human-degenerative disease related genes have close homologues in yeast. The reduced genetic redundancy of yeast facilitates visualization of the effect of a deleted or mutated gene. By manipulating growth conditions, yeast cells can survive only fermenting (low ROS levels) or respiring (increased ROS levels), which facilitates the elucidation of the mechanisms involved with acquisition of tolerance to oxidative stress. Furthermore, the yeast databases are the most complete of all eukaryotic models. In this work, we highlight the value of S. cerevisiae as a model to investigate the oxidative stress response and its potential impact on aging and age-related diseases.     

Autophagy and aging: New lessons from progeroid mice

It is widely-assumed that the autophagic activity of living cells decreases with age and probably contributes to the accumulation of damaged macromolecules and organelles during aging. Over the last few years, the study of segmental progeroid syndromes in which certain aspects of aging are manifested precociously or in exacerbated form, has increased our knowledge on the molecular basis of aging. We have recently reported the unexpected finding that distinct progeroid murine models exhibit an extensive basal activation of autophagy instead of the characteristic decline in this process occurring during normal aging. Further studies on Zmpste24-null progeroid mice, which are a reliable model of human Hutchinson-Gilford progeria, have revealed that the observed autophagic increase is associated with a series of metabolic alterations resembling those occurring under calorie restriction or in other situations reported to prolong lifespan. Here, we analyze these unexpected findings and discuss their possible implications for the development of premature aging.

Addendum to: Mariño G, Ugalde AP, Salvador-Montoliu N, Varela I, Quirós PM, Cadiñanos J, van der Pluijm I, Freije JM, López-Otín C. Premature aging in mice activates a systemic metabolic response involving autophagy induction. Hum Mol Genet 2008; 17:2196–211.     

Immunopathology of autoimmune gastritis: lessons from mouse models

Autoimmune gastritis in humans is a chronic inflammatory disease of the stomach accompanied by specific destruction of gastric parietal and zymogenic cells resulting in pernicious anemia. Human gastritis can be accurately reproduced in mice and is characterised by autoantibodies to the alpha- and beta-subunits of the gastric H/K ATPase (the enzyme responsible for gastric acid secretion) and cellular destruction of parietal and zymogenic cells within the gastric gland. Studies with these mouse models have given us our current concepts of the immunopathogenesis of the gastritis. Mouse models have shown that a T cell response is generated to the alpha- and beta-subunits of the H/K ATPase and that an immune response to the beta-subunit seems to be required for disease initiation. Using these models, we have defined key events associated with a damaging autoimmune response to the gastric H/K ATPase. The mechanisms associated with the cellular destruction associated with autoimmune gastritis are not know, but may involve signaling through death inducing pathways such as the Fas/FasL and TNF/TNFR pathways. This knowledge should permit us to develop strategies to prevent and treat the gastritis.     

Nutrition,aging and cancer: lessons from dietary intervention studies

There is convincing epidemiological and clinical evidence that, independent of aging, lifestyle and, notably, nutrition are associated with development or progression of major human cancers, including breast, prostate, colorectal tumors, and an increasingly large collection of diet-related cancers. Mechanisms underlying this association are mostly related to the distinct epigenetic effects of different dietary patterns. In this context, Mediterranean diet has been reported to significantly reduce mortality rates for various chronic illnesses, including cardiovascular diseases, neurodegenerative diseases and cancer. Although many observational studies have supported this evidence, dietary intervention studies using a Mediterranean dietary pattern or its selected food components are still limited and affected by a rather large variability in characteristics of study subjects, type and length of intervention, selected end-points and statistical analysis. Here we review data of two of our intervention studies, the MeDiet study and the DiMeSa project, aimed at assessing the effects of traditional Mediterranean diet and/or its component(s) on a large panel of both plasma and urine biomarkers. Both published and unpublished results are presented and discussed.     

Immunology of fungal infections: lessons learned from animal models

The continuing AIDS epidemic coupled with increased usage of immunosuppressive drugs to prevent organ rejection or treat autoimmune diseases has resulted in an increase in individuals at risk for acquiring fungal diseases. These concerns highlight the need to elucidate mechanisms of inducing protective immune responses against fungal pathogens. Consequently, several experimental models of human mycoses have been developed to study these diseases. The availability of transgenic animal models allows for in-depth analysis of specific components, receptors, and signaling pathways that elicit protection against fungal diseases. This review focuses on recent advances in our understanding of immune responses to fungal infections gained using animal models.     

Mechanisms of APC-driven tumorigenesis: lessons from mouse models.

Colorectal cancer still represents one of the most common causes of morbidity and mortality among Western populations. The adenomatous polyposis coli (APC) gene, originally identified as the gene responsible for familial adenomatous polyposis (FAP), an inherited predisposition to multiple colorectal tumors, is now considered as the true "gatekeeper" of colonic epithelial proliferation. It is mutated in the vast majority of sporadic colorectal tumors, and inactivation of both APC alleles occurs at early stages of tumor development in man and mouse. The study of FAP has also led to one of the most consistent genotype-phenotype correlations in hereditary cancer. However, great phenotypic variability is still observed not only among carriers of the identical APC mutation from unrelated families but also from within the same kindred. The generation of several mouse models carrying specific Apc mutations on the same inbred genetic background has confirmed the genotype-phenotype correlations initially established among FAP patients, as well as provided important insights into the mechanisms of colorectal tumor formation. Here we review the major features of the available animal models for FAP and attempt the formulation of a hypothetical model for APC-driven tumorigenesis based on the observed genetic and phenotypic variability in mouse and man.     

The core-binding factor leukemias: lessons learned from murine models

The recent development of murine models of core-binding factor leukemias has provided important insights into the underlying molecular pathology of this common subtype of acute myeloid leukemia. Evidence from these models supports the idea that acute myeloid leukemia 1/core-binding factor beta-subunit (AML1/CBFbeta) has a critical role in the control of the self-renewal capacity of hematopoietic stem cells and their progeny. Moreover, the accumulated data demonstrate that the expression of translocation-encoded AML1 or CBFbeta fusion proteins are insufficient by themselves to induce a full leukemic phenotype. The models that have been developed should prove to be of value for defining the range of mutations that can cooperate with AML1/CBFbeta fusion proteins, and for assessing novel therapies targeted toward the pathways that are altered by the expression of these fusion proteins.     

Effector T cells in rheumatoid arthritis: lessons from animal models

The development of an immune response to self antigens drives naive T cells to differentiate into subsets of CD8(+) and CD4(+) effector cells including T(H)1, T(H)2, cells and the more recently described T(H)17, and regulatory T cells (T(reg)). Rheumatoid arthritis is an autoimmune disease that engages an uncontrolled influx of inflammatory cells to the joints, eventually leading to joint damage. The role that effector T cells play in the local or systemic maintenance of, or protection against, inflammation and subsequent joint damage is now becoming better understoodthrough the use of animal models. In this review, we will explore the different animal models of RA, and their contribution to elucidating the role that effector T cells play in the regulation, induction, and maintenance of inflammatory joint disease. This understanding will aid in the design of more effective therapeutic strategies for rheumatoid arthritis and other autoimmune disorders.     

Size effects in nonpolar solvation: lessons from two simple models

Size dependence of the solute chemical potential mu(u) is examined using the Ornstein-Zernike equation for two models of the nonpolar solute-solvent interactions. Simple Lennard-Jones interactions are assumed in the first model while the Lennard-Jones potential is distributed over the solute volume in the second model similar to the Hamaker theory for the colloid dispersion forces. In both models, while mu(u) rises asymptotically as the third power of the solute size in agreement with asymptotic solution of the scaled particle theory, it increases faster at smaller sizes. Deviations from the cubic law are more pronounced at higher solvent densities and stronger molecular interactions. Within a relatively narrow size range typical for small organic molecules, mu(u) can be approximated with a polynomial of the third or even the second power. However, the latter approximation is less accurate and cannot be employed for extrapolation to the larger size region.     

Diabetic embryopathy and fuel-mediated organ teratogenesis: lessons from animal models

The growing recognition that faulty maternal metabolism during early organogenesis may be implicated in the increased incidence of birth defects in pregnancies complicated by diabetes has prompted worldwide efforts to institute improved preconceptional metabolic regulation. However, the failure to identify the periods of greatest risk for diabetic embryopathy, the mediating teratogen(s), and the underlying mechanisms have complicated attempts to establish precise therapeutic guidelines and targets. Some of the reported in vivo and in vitro experiences with rodent models have been reviewed to derive relevant insights. Substantial literature indicates that diabetes (experimental as well as spontaneous) in pregnant rats and mice is attended by retardation of growth and developmental delay during embryogenesis, and a variable incidence of birth defects. Poor metabolic regulation of the diabetic mother during early organogenesis may also be followed by subsequent resorption of the conceptus at the site of implantation. Vulnerability to diabetes-related resorptions and all other forms of embryopathy appears to begin during the early postimplantation period and is greatest near the onset of neurolation. Overall susceptibility is markedly influenced by genetic factors and may be modified by the antecedent metabolic exposures of the conceptus ("carry-over effects"). Mediation for the anomalous embryo development in pregnancies of diabetic rodents appears to be multifactorial; all the aberrant fuels and fuel-related components of "the diabetic state" (e.g. high glucose; ketones; somatomedin inhibitor(s); osmolality, etc.) which have been tested to date display dysmorphogenic potential ("fuel-mediated organ terato-genesis") in vitro. All tissues in the conceptus appear to be at risk. Dose-response relationships for the individual metabolic teratogens may be influenced by additive and synergistic interactions so that the integrated possibilities cannot be assessed fully by measurements confined to a single fuel or fuel-related component. In the context of the day-to-day variability in diabetes "control" of the poorly regulated mother, and the relatively longer duration of organogenesis, these multifactorial possibilities may account for the multiple birth defects that can occur in individual offspring, and the seemingly non-specific pattern of diabetic embryopathy. Insulin therapy diminishes the dysmorphogenic effects of "the diabetic state" in rodents with experimental or spontaneous diabetes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Pregnancy-associated homeostasis and dysregulation: lessons from genetically modified animal models

Unlimitedly proliferating cells need to acquire the telomere DNA maintenance mechanism, to counteract possible shortening through multiple rounds of replication and segregation of linear chromosomes. Most human cancer cells express telomerase whereas the other cells utilize the alternative lengthening of telomeres (ALT) pathway to elongate telomere DNA. It is suggested that ALT depends on the recombination between telomere repetitive DNAs. However, the molecular details remain unknown. Recent studies have provided evidence of special structures of telomere DNA and genes essential for the phenotypes of ALT cells. The molecular models of the ALT pathway should be validated to elucidate recombination-mediated telomere maintenance and promote the applications to anti-cancer therapy.     

Some lessons about models from Michaelis and Menten

Michaelis and Menten's classic 1913 paper on enzyme kinetics is used to draw some lessons about the relationship between mathematical models and biological reality.     

Genetic susceptibility to infectious disease: lessons from mouse models of leishmaniasis

Susceptibility to infectious disease is influenced by multiple host genes, most of which are low penetrance QTLs that are difficult to map in humans. Leishmaniasis is a well-studied infectious disease with a variety of symptoms and well-defined immunological features. Mouse models of this disease have revealed more than 20 QTLs as being susceptibility genes, studies of which have made important contributions to our understanding of the host response to infection. The functional effects of individual QTLs differ widely, indicating a networked regulation of these effects. Several of these QTLs probably also influence susceptibility to other infections, indicating that their characterization will contribute to our understanding of susceptibility to infectious disease in general.     

Regulation of immunity to malaria: valuable lessons learned from murine models

A major advance in immunology has been the establishment of a framework for analysing how certain immune responses dominate following exposure to a particular pathogen or antigen. CD4(+) T helper (Th) cells can be separated into two major subsets which mediate qualitatively distinct cell-mediated (Th1) and humoral (Th2) immune responses. Immunity to most pathogens can be broadly categorized into a predominant protective response of either type. A characteristic of murine malarias is that primary infections with asexual erythrocytic parasites (the pathogenic stage of the malaria life cycle) generate a host protective immune response with a broad spectrum of Th1- and Th2-type CD4(+) T-cell involvement and so can be examined as models of the interaction of Th1 and Th2 cells during an immune response to an infectious agent. Andrew Taylor-Robinson here describes recent events in the dissection of the mechanisms responsible for the generation of protective immunity to Plasmodium chabaudi chabaudi and other experimental malarias in mice.