Human immunodeficiency virus,atherosclerosis and Chlamydophila pneumoniae

Chlamydophila pneumoniae (C. pneumoniae) is an obligate, intracellular bacterium associated with a wide variety of acute and chronic diseases. C. pneumoniae infection is characterized by persistence and immunopathological damage to host target tissues, including the lung. Over the past 20 years, a variety of studies have investigated a possible link between C. pneumoniae infection and atherosclerosis, because of its role in all stages of atherosclerosis, from initial inflammatory lesions to plaque rupture. In the current highly active antiretroviral therapy (HAART) era, many human immunodeficiency virus (HIV)-infected patients are experiencing health problems that accompany the aging process, mainly the risk of cardiovascular disease (CVD). There is renewed interest in a link between atherosclerotic CVD and as yet poorly defined environmental exposures, including infectious agents. On the one hand, the patient with HIV and lipodystrophy caused by HAART and exacerbated by C. pneumoniae infection could be a factor of risk for atherosclerosis. An assessment of the therapy against C. pneumoniae and HAART should always be conducted. It is advisable that HIV-acquired immune deficiency syndrome patients undergo a serological test to determine exposure to C. pneumoniae and to assess treatment options. On the other hand, in patients with a positive serology to C. pneumoniae, an increment of the body mass index has been found; therefore, it is probable that the recurrent infection may play an important role in creating adverse endothelial conditions allowing the infection by C. pneumoniae in its chronic form, to damage the endothelial surface. Vascular studies would be necessary for corroboration.     

Roles of FGF signaling in stem cell self-renewal, senescence and aging

The aging process decreases tissue function and regenerative capacity, which has been associated with cellular senescence and a decline in adult or somatic stem cell numbers and self-renewal within multiple tissues. The potential therapeutic application of stem cells to reduce the burden of aging and stimulate tissue regeneration after trauma is very promising. Much research is currently ongoing to identify the factors and molecular mediators of stem cell self-renewal to reach these goals. Over the last two decades, fibroblast growth factors (FGFs) and their receptors (FGFRs) have stood up as major players in both embryonic development and tissue repair. Moreover, many studies point to somatic stem cells as major targets of FGF signaling in both tissue homeostasis and repair. FGFs appear to promote self-renewing proliferation and inhibit cellular senescence in nearly all tissues tested to date. Here we review the role of FGFs and FGFRs in stem cell self-renewal, cellular senescence, and aging.     

Kidney aging: from phenotype to genetics

Aging is a physiological process that causes structural and functional changes in human body systems, sometimes leading to various organ failure. As far as the kidney is concerned, both genetic factors and environmental agents may influence the tissues damage in elderly people and the related loss of function. On the other hand, functional adaptations to structural changes appear to be compromised by co-morbid conditions that are frequently found in elderly people, such as atherosclerosis and hypertension. It is not yet known whether physiological aging is inevitably accompanied by a decline in renal function or how rapidly it might happen. The discovery of molecular mechanisms responsible for tissue damage in aging could offer new perspectives on interventions. The role of nitric oxide, oxidative stress, the renin-angiotensin system, changes in length of telomeres, and klotho gene expression are important subjects for further in-depth studies about aging. A better understanding of physiological renal aging could improve the clinical approach to this process and widen the therapeutic possibilities offered by transplantation.     

Impairment of regeneration in aging: appropriateness or stochastics?

There is a viewpoint that suppression of the proliferative capacity of cells and impairment of the regeneration of tissues and organs in aging are a consequence of specially arisen during evolution mechanisms that reduce the risk of malignant transformation and, thus, protect against cancer. We believe that the restriction of cell proliferation in an aging multicellular organism is not a consequence of implementing a special program of aging. Apparently, such a program does not exist at all and aging is only a “byproduct” of the program of development, implementation of which in higher organisms suggests the need for the emergence of cell populations with very low or even zero proliferative activity, which determines the limited capacity of relevant organs and tissues to regenerate. At the same time, it is the presence of highly differentiated cell populations, barely able or completely unable to reproduce (neurons, cardiomyocytes, hepatocytes), that ensures the normal functioning of the higher animals and humans. Apparently, the impairment of regulatory processes, realized at the neurohumoral level, still plays the main role in the mechanisms of aging of multicellular organisms, not just the accumulation of macromolecular defects in individual cells. It seems that the quality of the cells themselves does not worsen with age as much as reliability of the organism control over cells, organs and tissues, which leads to an increase in the probability of death.     

Halofuginone for fibrosis,regeneration and cancer in the gastrointestinal tract

Organ fibrosis and architectural remodeling can severely disrupt tissue function, often with fatal consequences. Fibrosis is the end result of chronic inflammatory reactions induced by a variety of stimuli, and the key cellular mediator of fibrosis comprises the myofibroblasts which, when activated, serve as the primary collagen-producing cells. Complex links exist between fibrosis, regeneration and carcinogenesis, and the concept that all organs contain common tissue fibrosis pathways that could be potential therapeutic targets is an attractive one. Because of the major impact of fibrosis on human health there is an unmet need for safe and effective therapies that directly target fibrosis. Halofuginone inhibits tissue fibrosis and regeneration, and thereby affects the development of tumors in various tissues along the gastrointestinal tract. The high efficacy of halofuginone in reducing the fibrosis that affects tumor growth and tissue regeneration is probably due to its dual role in inhibiting the signaling pathway of transforming growth factor β, on the one hand, and inhibiting the development of Th17 cells, on the other hand. At present halofuginone is being evaluated in a clinical trial for other fibrotic indication, and any clinical success in that trial would allow the use of halofuginone, also for all other fibrotic indications, including those of the gastrointestinal tract.     

Regeneration in axolotls: a model to aim for!

Urodele amphibians such as the axolotl are the champions of tissue regeneration amongst vertebrates. These animals have mastered the ability to repair and replace most of their tissues following damage or amputation even well into adulthood. In fact it seems that the ability of these organisms to regenerate perfectly is not affected by their age. In addition to being able to regenerate, these animals display a remarkable resistance to cancer. They therefore represent a unique model organism to study regeneration and cancer resistance in vertebrates. The need for this research is even more pressing at the dawn of the 21st century as we are faced with an ever aging world population which has to deal with an increase in organ failure and cancer incidence. Hopefully, this mini review will put in perspective some of the reasons why studying tissue regeneration in salamanders could yield significant knowledge to help regenerative medicine achieve the desired goal of allowing humans to repair and regenerate some of their own tissues as they age.     

Role of the endothelium and blood stasis in the appearance of varicose veins.

Today, chronic venous insufficiency affects millions of people but the investigation of veins and of venous diseases is still very poor. Additionally, the mechanism of the occurrence of varicose veins is not understood. Blood stasis is often associated with these pathological situations and we propose that resulting ischemic conditions can trigger the endothelium to release inflammatory mediators and growth factors. On one hand, the inflammatory mediators will recruit and activate neutrophils, which then infiltrate the venous wall and damage components of the extracellular matrix. On the other hand, growth factors induce smooth muscle cell migration, proliferation and de-differentiation into the synthetic phenotype, all together leading to the formation of neointima. These processes, being repeated over time, would eventually lead to alterations of the venous wall as observed in varicose veins. Venotropic drugs are used to treat chronic venous insufficiency. They are able to increase venous tone and to decrease vein and capillary permeability but they are also able to protect the endothelial cells against ischemia. Indeed, they target complexes of the mitochondrial respiratory chain and maintain ATP production during hypoxia. Hence, the cells are resistant to ischemia and do not release inflammatory mediators and growth factors. These drugs should thus be able to prevent the alterations of the venous wall induced by blood stasis.     

Pathological aging of the vascular endothelium: are endothelial progenitor cells the sentinels of the cardiovascular system?

Aging is associated with vascular endothelial dysfunction, which ultimately leads to atherosclerosis. On the other hand, it is clear that in young patients with risk factors for cardiovascular diseases (CVD), endothelial dysfunction is an early marker of the ongoing atherogenic process. It is therefore tempting to speculate that risk factors for CVD accelerate the aging process. The aging of an endothelial cell (EC) is not chronological but rather dependent on its replication rate. ECs have a finite number of divisions and enter replicative senescence after exhaustion of this potential. Telomere attrition is believed to be responsible for this phenomenon. Upon reaching a critical minimal telomere length, ECs enter a nondividing state of replicative senescence. Recently, endothelial progenitor cells originating from the bone marrow have been isolated from the circulation. They integrate into the endothelial layer of the vessel and contribute to healing, ischemic repair and angiogenesis. A completely new field of investigation is now open. Are endothelial progenitor cells sensitive to the aging process? Do they prevent endothelial dysfunction? Are they the ultimate shield against the damages induced by risk factors for CVD? There are no definite answers to these questions, but the potential of these cells is tremendous and understanding their physiology is essential.     

内皮细胞功能异常与动脉粥样硬化的研究进展

血管内皮细胞参与构成人体的生理屏障和维持人体内环境稳态,并且为适应内环境的动态变化及满足人体不同组织新陈代谢的需要,不同组织的内皮细胞具有功能差异性和组织特异性.心脏血管内皮细胞参与维持心脏内环境的稳定,当内皮细胞因高脂血症、高血糖、氧化应激、炎症反应及其他代谢因素发生功能障碍,会参与心血管疾病的病理生理过程,例如动脉...     

R-spondin3 prevents mesenteric ischemia/reperfusion-induced tissue damage by tightening endothelium and preventing vascular leakage

Inflammation and vascular injury triggered by ischemia/reperfusion (I/R) represent a leading cause of morbidity and mortality in a number of clinical settings. Wnt and its homolog partners R-spondins, in addition to regulating embryonic development have recently been demonstrated to serve as wound-healing agents in inflammation-associated conditions. Here we ask whether R-spondins could prevent inflammation-associated tissue damage in ischemic disorders and thus investigate the role of R-spondin3 (R-spo3) in a mouse model of mesenteric I/R. We demonstrate that R-spo3 ameliorates mesenteric I/R-induced local intestinal as well as remote lung damage by suppressing local and systemic cytokine response and deposition of IgM and complement in intestinal tissues. We also show that decreased inflammatory response is accompanied by tightening of endothelial cell junctions and reduction in vascular leakage. We conclude that R-spo3 stabilizes endothelial junctions and inhibits vascular leakage during I/R and thereby mitigates the inflammatory events and associated tissue damage. Our findings uniquely demonstrate a protective effect of R-spo3 in I/R-related tissue injury and suggest a mechanism by which it may have these effects.     

Protein glycation: a firm link to endothelial cell dysfunction

The advanced glycation end products (AGEs) are a heterogeneous class of molecules, including the following main subgroups: bis(lysyl)imidazolium cross-links, hydroimidazolones, 3-deoxyglucosone derivatives, and monolysyl adducts. AGEs are increased in diabetes, renal failure, and aging. Microvascular lesions correlate with the accumulation of AGEs, as demonstrated in diabetic retinopathy or renal glomerulosclerosis. On endothelial cells, ligation of receptor for AGE (RAGE) by AGEs induces the expression of cell adhesion molecules, tissue factor, cytokines such as interleukin-6, and monocyte chemoattractant protein-1. A chief means by which AGEs via RAGE exert their effects is by generation of reactive oxygen species, at least in part via stimulation of NADPH oxidase. Diabetes-associated vascular dysfunction in vivo can be prevented by blockade of RAGE. Thus, agents that limit AGE formation, increase the catabolism of these species, or antagonize their binding to RAGE may provide new targets for vascular protection in diabetes.     

Host cell mobilization for in situ tissue regeneration

Although small, localized injuries can be healed through the body's normal reparative process, large traumatic injury overwhelms this system and may result in a deficit of functional recovery, despite the use of conventional reconstructive modalities. Cell-based approaches using tissue engineering and regenerative medicine techniques have offered new opportunities for treatment. Although the fundamental principles of cell-based therapies have been demonstrated clinically on multiple tissue systems, usually a donor tissue biopsy and ex vivo cell manipulation prior to implantation in vivo are necessary. The goal of the present study was to investigate whether host biologic resources and environmental conditions could be used for in situ tissue regeneration, which may eliminate the need for donor cell procurement and subsequent in vitro cell manipulation. To address this aim, we implanted a common biomaterial into mice and characterized the infiltrating cells to determine their regenerative potential. We showed that host cell infiltrates are not entirely comprised of inflammatory and fibroblast-like cells and the normal inflammatory process can be altered by incorporating anti-inflammatory agents that influence the formation of scar tissue. In addition, the infiltrating cells are capable of differentiating into multiple cell lineages, including osteogenic, myogenic, adipogenic, and endothelial lineages, if appropriate conditions are provided. These results suggest that it is possible to recruit a predominance of cells with multilineage potential into a biomaterial scaffold. Therefore, it may be possible to enrich the infiltrate with such cell types and control their fate, provided the proper substrate-mediated signaling can be imparted into the scaffold for in situ tissue regeneration.     

内皮细胞损伤与修复的研究进展

内皮细胞是重要代谢和内分泌器官,在调节血管功能中起重要作用。多种心脑血管疾病(如动脉粥样硬化、高血压、糖尿病血管并发症等)的发生发展与内皮损伤密切相关。然而血管内皮细胞损伤的机制尚未完全明了。大量研究表明,内皮细胞损伤机制主要涉及炎症反应和氧化应激。内皮祖细胞在修复损伤内皮过程中发挥重要作用。多种化学药物和中药,通过减少诱发因素、抑制炎症反应与氧化应激反应、延缓内皮细胞衰老等途径发挥内皮保护作用。     

Age-related modifications in human unstimulated whole saliva: a biochemical study

Human whole saliva contains a number of antimicrobial agents, and lysozyme, lactoferrin, secretory IgA and peroxidase are among the best known. Peroxidase catalyzes a reaction involved in the inhibition of bacterial growth and metabolism, and the prevention of hydrogen peroxide accumulation, thus protecting proteins from the action of oxygen and reactive oxygen species (ROS). To better understand the role played by the oxidative stress in the aging process, we studied the relationship between total protein content, peroxidase activity, malondialdehyde (MDA) and nitric oxide (NO) content of human unstimulated whole saliva in 169 healthy subjects subdivided into groups according to age. Our results show a significant decrease in peroxidase activity with age. Moreover, the increase in saliva lipid peroxide levels indicates an enhanced free radical production that may contribute to tissue damage. On the other hand, findings concerning human unstimulated whole saliva NO content showed a significant increase in elderly subjects, suggesting that an enhanced NO production might depend on a stimulation of leukocyte-inducible NO synthase (i-NOS) activity. Our results suggest that during aging the oral tissues may become more susceptible to environmental factors due to a modification in the balance between different antimicrobial agents.     

Melatonin enhances survival and preserves functional integrity of stem cells: A review

Despite state‐of‐the‐art pharmaceutical regimens, continuous improvements in diagnostic techniques as well as refinements in equipment and interventional procedures, many diseases remain refractory to conventional therapies. Recent advances in stem cell (SC) biology have opened an avenue to exploring its therapeutic potential in various disease entities, especially those that are ischemia‐related and refractory to conventional treatment. A number of experimental studies and clinical trials have already demonstrated promising outcomes. On the other hand, SC therapy is associated with major problems. For instance, ischemia, inflammation, and oxidative stress are some of the factors unfavorable for SC survival once SCs are implanted into the ischemic area in an attempt to enhance tissue regeneration and restore organ function. Melatonin, which is originally derived from pineal gland in the regulation of human circadian rhythms and sleep, is a potent free radical scavenger and metal chelator with the capacity to alleviate oxidative stress and inflammatory reactions as well as stabilizing cell membranes. Accumulating data have demonstrated that melatonin‐supported SC therapy is superior to SC alone for improving ischemia‐related organ dysfunction. In this review, we describe and interpret the potential role of melatonin in sustaining the survival and preserving the functional integrity of SC.     

Pathogenesis of idiopathic inflammatory myopathies

The idiopathic inflammatory myopathies, myositis, are characterized by a chronic course with decreased muscle endurance and by infiltrates of T lymphocytes and macrophages in muscle tissue. Treatment with immunosuppressives rarely leads to recovery of muscle function, despite abolishment of inflammatory cell infiltrates in muscle tissue. Therefore, other mechanisms than immune-mediated muscle fiber damage are likely to contribute to the pathogenesis. One such non-immune-mediated muscle dysfunction could be caused by a disturbed microcirculation due to capillary loss or to phenotypically changed endothelial cells in the capillaries. These aberrations may affect the micro-environment of muscle tissue and lead to local tissue hypoxia with development of a secondary metabolic myopathy. Another possible non-immune-mediated mechanism leading to muscle dysfunction is the newly identified endoplasmatic reticulum (ER) stress response in myositis. The ER stress response is thought to be a consequence of the up-regulation of major histocompatibility complex class I in muscle fibers. These newly identified molecular pathways could play a major role in the pathogenesis of myositis and could be important targets in the development of new therapies.