The cancer nuclear microenvironment: interface between light microscopic cytology and molecular phenotype

A definitive diagnosis of cancer may be rendered by microscopic assessment of only a few cells in an appropriate clinical setting due to the distinctive nuclear structure of most cancer cells in comparison to nuclei of normal human cells. The molecular architecture of non-neoplastic human nuclei--of the nuclear matrix and of matrix-associated proteins and nucleic acids--is being characterized in exquisite molecular detail. What is missing is the application of the findings and tools of molecular biology to understanding the cytological structure of cancer nuclei. This article delves into the basis of nuclear structure at different levels of resolution--light microscopic, electron microscopic, and molecular.     

Chromatin structure as a mediator of aging

The aging process is characterized by gradual changes to an organism’s macromolecules, which negatively impacts biological processes. The complex macromolecular structure of chromatin regulates all nuclear processes requiring access to the DNA sequence. As such, maintenance of chromatin structure is an integral component to deter premature aging. In this review, we describe current research that links aging to chromatin structure. Histone modifications influence chromatin compaction and gene expression and undergo many changes during aging. Histone protein levels also decline during aging, dramatically affecting chromatin structure. Excitingly, lifespan can be extended by manipulations that reverse the age-dependent changes to chromatin structure, indicating the pivotal role chromatin structure plays during aging.     

Deleted in breast cancer-1 (DBC-1) in the interface between metabolism,aging and cancer

DBC1 (deleted in breast cancer-1) is a nuclear protein that regulates cellular metabolism. Since alteration in cellular metabolism have been proposed to be the emerging ‘hallmark’ of cancer, it is possible that DBC1 may be implicated in the regulation of cancer cell energy metabolism. However, at this point any role of DBC1 in cancer is only speculative. In this review, we will discuss the new developments in DBC1 research, its molecular structure, regulatory roles and implication in metabolism, aging and cancer.     

Cellular and molecular mechanisms of aging: a review]

Since the beginning of this century, a large body of experimental data and observations accumulated concerning experimental and clinical gerontology. These data can be classified and analyzed according to the level of experimentation or observation as concerning aging at the molecular, cellular level or at higher levels of hierarchical organisation such as tissues, organs or the whole organism. Observations of these higher levels are mostly derived from epidemiological studies of human aging, horizontal studies or preferably vertical studies. The relative coherence of data collected at the molecular and cellular levels renders plausible a tentative of interpretation of aging phenomena at higher levels or hierarchical organisations from the tissues to the whole organism by using the data obtained at the molecular and cellular levels. The present article is a tentative for this kind or integrative interpretation of aging.     

A molecular rheostat at the interface of cancer and diabetes

Epidemiology studies revealed the connection between several types of cancer and type 2 diabetes (T2D) and suggested that T2D is both a symptom and a risk factor of pancreatic cancer. High level of circulating insulin (hyperinsulinemia) in obesity has been implicated in promoting aggressive types of cancers. Insulin resistance, a symptom of T2D, pressures pancreatic β-cells to increase insulin secretion, leading to hyperinsulinemia, which in turn leads to a gradual loss of functional β-cell mass, thus indicating a fine balance and interplay between β-cell function and mass. While the mechanisms of these connections are unclear, the mTORC1-Akt signaling pathway has been implicated in controlling β-cell function and mass, and in mediating the link of cancer and T2D. However, incomplete understating of how the pathway is regulated and how it integrates body metabolism has hindered its efficacy as a clinical target. The IQ motif containing GTPase activating protein 1 (IQGAP1)-Exocyst axis is a growth factor- and nutrient-sensor that couples cell growth and division. Here we discuss how IQGAP1-Exocyst, through differential interactions with Rho-type of small guanosine triphosphatases (GTPases), acts as a rheostat that modulates the mTORC1-Akt and MAPK signals, and integrates β-cell function and mass with insulin signaling, thus providing a molecular mechanism for cancer initiation in diabetes. Delineating this regulatory pathway may have the potential of contributing to optimizing the efficacy and selectivity of future therapies for cancer and diabetes.     

Chromatin template activity during aging in WI38 cells

A reduction in the chromatin template activity of WI38 cells of different ages has been demonstrated using (1) the endogenous RNA polymerase of the host cell and (2) exogenously supplied E. coli RNA polymerase. The consistency between these two methods suggests that the reduction in chromatin template activity of these cells is age-associated and may represent changes in gene activity during in vitro aging.     

Emerging role of sirtuins on tumorigenesis: possible link between aging and cancer

Aging is the strongest risk factor for cancer development, suggesting that molecular crosstalks between aging and tumorigenesis exist in many cellular pathways. Recently, Sirtuins (Sirt1-7), the mammalian homologues of aging-related sir2α in yeast, have been shown to modulate several major cellular pathways, such as DNA repair, inflammation, metabolism, cell death, and proliferation in response to diverse stresses, and may serve as a possible molecular link between aging and tumorignenesis. In addition, growing evidence suggests that sirtuins are directly implicated in the development of cancer, and they can act as either a tumor suppressor or promoter, depending on the cellular context and tumor types. While the functions of Sirt1 in tumorigenesis have been reported and reviewed in many studies, the connection between sirtuins 2-7 and the development of cancer is less established. Thus, this review will present the recent updates on the emerging roles of Sirt2-7 members in carcinogenesis. [BMB Reports 2013; 46(9): 429-438]     

Cancer and aging: a model for the cancer promoting effects of the aging stroma

The incidence of cancer rises exponentially with age in humans and many other mammalian species. Malignant tumors are caused by an accumulation of oncogenic mutations. In addition, malignant tumorigenesis requires a permissive tissue environment in which mutant cells can survive, proliferate, and express their neoplastic phenotype. We propose that the age-related increase in cancer results from a synergy between the accumulation of mutations and age-related, pro-oncogenic changes in the tissue milieu. Most age-related cancers derive from the epithelial cells of renewable tissues. An important element of epithelial tissues is the stroma, the sub-epithelial layer composed of extracellular matrix and several cell types. The stroma is maintained, remodeled and repaired by resident fibroblasts, supports and instructs the epithelium, and is essential for epithelial function. One change that occurs in tissues during aging is the accumulation of epithelial cells and fibroblasts that have undergone cellular senescence. Cellular senescence irreversibly arrests proliferation in response to damage or stimuli that put cells at risk for neoplastic transformation. Senescent cells secrete factors that can disrupt tissue architecture and/or stimulate nearby cells to proliferate. We therefore speculate that their presence may create a pro-oncogenic tissue environment that synergizes with oncogenic mutations to drive the rise in cancer incidence with age. Recent evidence lends support to this idea, and suggests that senescent stromal fibroblasts may be particularly adept at creating a tissue environment that can promote the development of age-related epithelial cancers.     

Chromatin supraorganization and extensibility in mouse hepatocytes with development and aging.

BACKGROUND: Chromatin supraorganization and extensibility, which lead to the formation of extended chromatin fibers (ECF), are affected by starvation and refeeding in adult mouse hepatocytes. It is expected that they could also change with mouse development and aging. METHODS: Methods used involved topochemistry, image analysis, microspectrophotometry, gravity action, and polarization microscopy. RESULTS: Increased nuclear areas and Feulgen-DNA amounts with advancing hepatocyte polyploidy were found with development and aging. A slightly less packed chromatin with more heterogeneously distributed condensation levels was detected in young and old mice. Con-A responsiveness was almost absent in young mice but very deep in aged mice. ECFs formed from nuclei of adult and aged mice but not from nuclei of young mice. The frequency of ECF formation with the long lysis protocol increased with aging. CONCLUSIONS: In young mice, a less packed chromatin state may be associated with more intense gene activity, thus increasing the DNA-nuclear matrix interactions, and inhibiting ECF formation. Reduced DNA-nuclear matrix interactions besides defects in heterochromatin formation may induce higher ECF formation and chromatin unpackaging in old mice. We suggest that differences in Con-A staining relate to different gene activity with advancing development and aging.     

Gut bacteria in health and disease: a survey on the interface between intestinal microbiology and colorectal cancer

A healthy human body contains at least tenfold more bacterial cells than human cells and the most abundant and diverse microbial community resides in the intestinal tract. Intestinal health is not only maintained by the human intestine itself and by dietary factors, but is also largely supported by this resident microbial community. Conversely, however, a large body of evidence supports a relationship between bacteria, bacterial activities and human colorectal cancer. Symbiosis in this multifaceted organ is thus crucial to maintain a healthy balance within the host-diet-microbiota triangle and accordingly, changes in any of these three factors may drive a healthy situation into a state of disease. In this review, the factors that sustain health or drive this complex intestinal system into dysbiosis are discussed. Emphasis is on the role of the intestinal microbiota and related mechanisms that can drive the initiation and progression of sporadic colorectal cancer (CRC). These mechanisms comprise the induction of pro-inflammatory and pro-carcinogenic pathways in epithelial cells as well as the production of (geno)toxins and the conversion of pro-carcinogenic dietary factors into carcinogens. A thorough understanding of these processes will provide leads for future research and may ultimately aid in development of new strategies for CRC diagnosis and prevention.     

Chromatin structure of the molecular ends of Oxytricha macronuclear DNA: phased nucleosomes and a telomeric complex

Oxytricha macronuclear DNA exists as approximately 24 X 10(6) gene-sized molecules terminating with a C4A4 repeat. DNA-protein interactions at the ends of bulk macronuclear molecules were probed with micrococcal nuclease and methidiumpropyl-EDTA X Fe(II) (MPE X Fe[II]). The ends were indirectly labeled by hybridizing with (C4A4)2. Alternatively, a novel method using MPE X FE(II) as a probe and directly labeling the 3' ends with terminal transferase was implemented. A terminal complex involving approximately 100 bp with nucleosomes phased inward from the complex was found to be characteristic of most or all of the ends. Analysis of two specific genes confirmed the pattern and showed that the special structure was on both ends of each molecule. We conclude that a DNA-protein complex involving 100 bp and terminating with the C4A4 repeat can be sufficient to provide the fundamental functions of telomeres, allowing linear DNA replication and conferring stability of linear DNA.