Melatonin and human cancer

A number of studies performed in vitro and on experimental animals supported the view that pineal gland inhibits neoplastic growth. Data in humans are scanty and controversial. In the present study we measured serum melatonin (MT), prolactin (PRL) and growth hormone (GH) concentrations, at 08.00 and 24.00, in 132 cancer patients and in 58 healthy control subjects. The patients were stratified according to histology and stage of disease as follows: 30 stage I–II and 45 stage III–IV breast cancer (BC); 39 stage III–IV lung cancer; 18 advanced gastrointestinal (GI) cancer. We also measured MT levels, at the same time-points, in 20 women with primary BC before and after radical mastectomy. Finally, we evaluated the circadian rhythm of serum MT in 18 patients with advanced cancer. On the whole, the patients with advanced tumors showed serum MT levels significantly higher than controls, without any correlation with PRL and GH values. When looking at stage III–IV vs stage I–II BC patients, significantly higher MT levels have been found in the former group. The surgical removal of the primary BC was not associated with any changes in MT values at both time points considered. A highly significant rhythm of serum MT was recorded in advanced cancer patients and the rhythmic parameters were substantially superimposable on those of the control subjects.     

Mitochondria and human cancer

The better part of a century has passed since Otto Warburg first hypothesized that unique phenotypic characteristics of tumor cells might be associated with an impairment in the respiratory capacity of these cells. Since then a number of distinct differences between the mitochondria of normal cells and cancer cells have been observed at the genetic, molecular, and biochemical levels. This article begins with a general overview of mitochondrial structure and function, and then outlines more specifically the metabolic and molecular alterations in mitochondria associated with human cancer and their clinical implications. Special emphasis is placed on mtDNA mutations and their potential role in carcinogenesis. The potential use of mitochondria as biomarkers for early detection of cancer, or as unique cellular targets for novel and selective anti-cancer agents is also discussed.     

Chromosomal instability and human cancer

Genetic instability is a defining feature of human cancer. The main type of genetic instability, chromosomal instability (CIN), enhances the rate of gross chromosomal changes during cell division. CIN is brought about by mutations of CIN genes, i.e. genes that are involved in maintaining the genomic integrity of the cell. A major question in cancer genetics is whether genetic instability is a cause and hence a driving force of tumorigenesis. A mathematical framework for studying the somatic evolution of cancer sheds light onto the causal relations between CIN and human cancer.     

Coagulation proteases and human cancer

Tumours are capable of activating blood coagulation through the expression of procoagulant molecules such as tissue factor, cancer procoagulant and hepsin. Initiation of the clotting cascade results in the generation of the activated serine proteases factor VIIa, factor Xa and thrombin. These proteases act via protease-activated receptors and tissue factor to alter gene expression, thereby modulating tumour cell growth, invasion, metastasis and angiogenesis.     

Interleukin-8 and human cancer biology

The aggressive nature of metastatic human cancer has been shown to be related to numerous abnormalities in growth factors and their receptors. These perturbations confer a tremendous growth advantage to the malignant cells. Interleukin-8 (IL-8), originally discovered as a chemotactic factor for leukocytes, has recently been shown to contribute to human cancer progression through its potential functions as a mitogenic, angiogenic, and motogenic factor. While it is constitutively detected in human cancer tissues and established cell lines, IL-8 expression is regulated by various tumor microenvironment factors, such as hypoxia, acidosis, nitric oxide, and cell density. Understanding the mechanisms of both inducible and constitutive IL-8 expression will be helpful in designing potential therapeutic strategies of targeting IL-8 to control tumor growth and metastasis. In this review, the role and regulation of IL-8 expression in the growth and metastasis of human cancer with a focus on human pancreatic adenocarcinoma will be discussed.     

Oncogenes and human breast cancer.

The role of oncogenes in breast tumorigenesis is unclear. Alterations and/or amplification of several oncogene sequences have been observed in primary human breast tumors, in breast tumor cell lines, and in mammary tumors in model systems. In principle, such alterations could be sites of primary lesions for human breast cancer, causes of tumor progression or metastasis, or simply secondary lesions of highly aberrant tumor genomes. The present study tested genetic linkage of breast cancer susceptibility to nine oncogenes in 12 extended families including 87 affected individuals. Lod scores for close linkage of each candidate sequence to breast cancer were -19.6 for HRAS, -12.3 for KRAS2, -1.0 for NRAS, -6.0 for MYC, -6.1 for MYB, -8.2 for ERBA2, -7.9 for INT2, and -5.1 for RAF1. Regions of chromosome 11p associated with tumor homozygosity and the region of 3p carrying the gene for Von Hippel-Lindau disease could also be excluded from linkage to human breast cancer. The 5-kb allele of the MOS oncogene, previously proposed to be associated with breast cancer, was absent in these families, suggesting that polymorphism at this locus is not associated with inherited susceptibility. These results strongly suggest that oncogenes are not the sites of primary alterations leading to breast cancer. On the other hand, alterations in one or more of these sequences may be associated with tumor progression.     

Steroids and human breast cancer.

Normal mammary gland cells are sensitive to a number of hormones, of which estrogen and prolactin exert the most obvious effects. Some breast cancer cells are also sensitive. Cytoplasmic receptor sites for each hormone are responsible for the interaction between the hormone and the cell. The presence of estrogen receptor has been especially studied in humans. Data collected from several sources are reviewed. The prese nce of estrogen receptors has been assayed in 154 primary breast tumors and 72 metastatic breast tumors for correlation with response to endocri ne therapy. Positive values were found in 70% of primary and 58% of metastatic specimens. Of 211 treatment trials, ablative therapy produced objective tumor regressions in 33%. Of the 94 trials with negative receptor values, only 8 were successful while 59 of the 107 trials in patients with positive receptor values succeeded. In those with borderline tumor receptor, values had a 30% response. With additive therapy, 34% of 170 trials showed tumor regression. Of these, 82 had negat ive receptor values but 8% were successful, whereas of 85 with positive receptor values, 60% were favorable. With miscellaneous therapy, 27% of 55 trials gave responses to a variety of endocrine therapies, including antiestrogens. The 32 with negative receptor values gave 16% of favorable responses whereas 43% of 23 trials in those with positive receptor values succeeded. Estrogen receptor assays performed routinely would spare patients with negative results from unnecessary major ablative therapy. Of those with positive findings, 55-60% might be benefited. The fact that all with positive receptor values do not respond is attributed to the fact that this is only part of the hormonal control system. Other biochemical lesions are assumed to have occurred in patients when endocrine therapy fails despite positive estrogen receptor levels as measured.     

DNA tumor viruses and human cancer

There is a strong association between viruses and the development of human malignancies. A group of oncogenic DNA viruses exists in the human population today, members of which serve as infectious agents of cancer worldwide. The group includes the Epstein-Barr virus, Kaposi's sarcoma-associated herpesvirus, human papillomaviruses and human polyomaviruses. Globally, it is estimated that 20% of all cancers are linked to infectious agents. Studies of DNA viruses have contributed to our current understanding of the key molecular players in the transformation process. Research has also shed light on the molecular mechanisms of tumorigenesis that are employed by these viruses and there are indications that cofactors could be required for viral oncogenicity in some cases.     

Aberrant AID expression and human cancer development

Cancer develops via a multistep process that occurs through the accumulation of somatic mutations of tumor-related genes that govern cell proliferation, regeneration, and apoptosis. The question how normal cells acquire the genetic changes that lead to malignant transformation is, however, unknown at present. Activation-induced cytidine deaminase (AID) produces immune-diversity by inducing somatic hypermutations and class-switch recombinations in human immunoglobulin genes. Unfortunately, this function of AID as a genome mutator could aim at the generation of somatic mutations in various host genes of non-lymphoid tissues and contribute to tumorgenesis. Notably, aberrant AID expression can be triggered by several pathogenic factors, including Helicobacter pylori infection and proinflammatory cytokine stimulation, in human epithelial cells, whereas AID expression is absent in those cells under physiologic conditions. Thus, aberrant AID activity in epithelial tissues may provide the critical link between inflammation, somatic mutations, and cancer development.     

Estrone sulfate and sulfatase activity in human breast cancer and endometrial cancer

Estrone sulfate (E1-S) in the serum and tissues of patients with breast cancer or endometrial cancer was measured by a direct radioimmunoassay without hydrolysis. The concentration of E1-S in breast cancer tissue was 1.64 +/- 0.28 ng/g wet wt (+/- SE), lower than in surrounding normal breast tissue (4.46 +/- 1.23). Estradiol-17 beta(E2)/E1-S was higher in endometrial cancer tissue than normal endometrial tissue. Estrone sulfatase activity in breast cancer tissue was 0.81 +/- 0.23 nmol/h/mg protein, higher than in surrounding normal breast tissue (0.35 +/- 0.11). These results suggest that E1-S, which is abundant in the peripheral circulation, is hydrolyzed by sulfatase in breast cancer tissue or endometrial cancer tissue and liberates free estrogens, which may stimulate the growth of these malignant tumors.     

Chromosome abnormalities in human cancer and leukemia

The meaning and application of chromosomal (cytogenetic, karyotypic) changes in human leukemia and cancer have been succinctly reviewed in this article. Thus, the usefulness of these changes in the diagnosis, classification and prognosis of various leukemic conditions and, more recently, of solid tumors is stressed and their application to molecular studies indicated. The meaning of primary (specific) and additional (secondary) karyotypic changes in malignant and benign tumors is discussed. Tables containing the common cytogenetic changes in leukemias and tumors, including benign ones, are included.     

Platelet-derived growth factor signaling and human cancer

Platelet-derived growth factor (PDGF) is a critical regulator of mesenchymal cell migration and proliferation. The vital functions of PDGFs for angiogenesis, as well as development of kidney, brain, cardiovascular system and pulmonary alveoli during embryogenesis, have been well demonstrated by gene knock-out approaches. Clinical studies reveal that aberrant expression of PDGF and its receptor is often associated with a variety of disorders including atherosclerosis, fibroproliferative diseases of lungs, kidneys and joints, and neoplasia. PDGF contributes to cancer development and progression by both autocrine and paracrine signaling mechanisms. In this review article, important features of the PDGF isoforms and their cell surface receptor subunits are discussed, with regards to signal transduction, PDGF-isoform specific cellular responses, and involvement in angiogensis, and tumorstromal interactions.     

TP53 and mutations in human cancer

TP53 is the most frequently mutated gene in human cancer, with a predominance of missense mutations scattered over 200 codons. In many cancers, specific mutation patterns can be identified, which are shaped by site-specific mutagenesis and by biological selection. In tobacco-related cancers (lung, head and neck), organ-specific patterns are observed, with many mutations compatible with the ones experimentally induced by tobacco carcinogens. In several other cancers, such as squamous cell carcinoma of the oesophagus or hepatocellular carcinoma (HCC), mutation patterns show geographic variations between regions of high and low incidence, suggesting a role for region-specific risk factors. HCC from high-incidence regions showing also a high prevalence of a specific Ser-249 TP53 mutation is one of the most striking examples of a mutagen fingerprint. All such assessments are useful to generate clues on the mutagenic mechanisms involved in human cancer. Moreover, it has been shown that DNA retrieved from plasma can be successfully used for detection of TP53 mutations, which gives hope for earlier more accurate detection of human cancers.