Showing papers in "Journal of Molecular Medicine in 1999"
TL;DR: Current evidence indicates that VEGF is essential for embryonic vasculogenesis and angiogenesis, and both therapeuticAngiogenesis using recombinant V EGF or VEGFs gene transfer and inhibition of VEGf-mediated pathological angiogenic are being pursued.
Abstract: Vascular endothelial growth factor (VEGF) is a fundamental regulator of normal and abnormal angiogenesis. Recent evidence indicates that VEGF is essential for embryonic vasculogenesis and angiogenesis. Furthermore, VEGF is required for the cyclical blood vessel proliferation in the female reproductive tract and for longitudinal bone growth and endochondral bone formation. Substantial experimental evidence also implicates VEGF in pathological angiogenesis. Anti-VEGF monoclonal antibodies or other VEGF inhibitors block the growth of many tumor cell lines in nude mice. Furthermore, the concentrations of VEGF are elevated in the aqueous and vitreous humors of patients with proliferative retinopathies such as the diabetic retinopathy. In addition, VEGF-induced angiogenesis results in a therapeutic benefit in several animal models of myocardial or limb ischemia. Currently, both therapeutic angiogenesis using recombinant VEGF or VEGF gene transfer and inhibition of VEGF-mediated pathological angiogenesis are being pursued.
1,206 citations
TL;DR: The properties of the 17–1A antigen are discussed concerning tumor biology and the function of the molecule, which functions as an Epithelial Cell Adhesion Molecule and the name Ep-CAM is suggested.
Abstract: The glycoprotein recognized by the monoclonal antibody (mAb) 17–1A is present on most carcinomas, which makes it an attractive target for immunotherapy. Indeed, adjuvant treatment with mAb 17–1A did successfully reduce the 5 years mortality among colorectal cancer patients with minimal residual disease. Currently the antibody is approved for clinical use in Germany, and is on its way to approval in a number of other countries. New immunotherapeutic strategies targeting the 17–1A antigen are in development or even in early-phase clinical trials. Therefore, a better understanding of the biology of the 17–1A antigen may result in improved strategies for the treatment and diagnosis of human carcinomas. In this review the properties of the 17–1A antigen are discussed concerning tumor biology and the function of the molecule. This 40-kDa glycoprotein functions as an Epithelial Cell Adhesion Molecule, therefore the name Ep-CAM was suggested. Ep-CAM mediates Ca2+-independent homotypic cell–cell adhesions. Formation of Ep-CAM-mediated adhesions has a negative regulatory effect on adhesions mediated by classic cadherins, which may have strong effects on the differentiation and growth of epithelial cells. Indeed, in vivo expression of Ep-CAM is related to increased epithelial proliferation and negatively correlates with cell differentiation. A regulatory function of Ep-CAM in the morphogenesis of epithelial tissue has been demonstrated for a number of tissues, in particular pancreas and mammary gland. The function of Ep-CAM should be taken into consideration when developing new therapeutic approaches targeting this molecule.
577 citations
TL;DR: A global (genome-wide) view of "gene function" in the regulation of the dynamic relationship between proliferation, differentiation, and apoptosis can provide new insights into cellular homeostasis and the origins of neoplasia.
Abstract: Genome-wide expression monitoring, a novel tool of functional genomics, is currently used mainly to identify groups of coregulated genes and to discover genes expressed differentially in distinct situations that could serve as drug targets. This descriptive approach, however, fails to extract "distributed" information embedded in the genomic regulatory network and manifested in distinct gene activation profiles. A model based on the formalism of boolean genetic networks in which cellular states are represented by attractors in a discrete dynamic system can serve as a conceptual framework for an integrative interpretation of gene expression profiles. Such a global (genome-wide) view of "gene function" in the regulation of the dynamic relationship between proliferation, differentiation, and apoptosis can provide new insights into cellular homeostasis and the origins of neoplasia. Implications for a rational approach to the identification of new drug targets for cancer treatment are discussed.
451 citations
TL;DR: In B-cell chronic lymphocytic leukemia (B-CLL), clonal chromosome aberrations are detected in approximately 40–50% of tumors when using conventional chromosome banding analysis, and by far the most frequent abnormality are deletions involving chromosome band 13q14, followed by deletions of the genomic region 11q22.
Abstract: In B-cell chronic lymphocytic leukemia (B-CLL) clonal chromosome aberrations are detected in approximately 40-50% of tumors when using conventional chromosome banding analysis. Most studies find trisomy 12 to be the most frequent chromosome aberration, followed by structural aberrations of the long arm of chromosomes 13 and 14. Trisomy 12 and the "14q+" marker are associated with shorter survival times, while the patients with 13q abnormalities have a favorable outcome, similar to those with a normal karyotype. The development of molecular cytogenetic techniques has greatly improved our ability to detect chromosome aberrations in tumor cells. Using fluorescence in situ hybridization, chromosome aberrations can be detected not only in dividing cells but also in interphase nuclei, an approach referred to as interphase cytogenetics. The prevalence of specific aberrations in B-CLL is currently being reassessed by interphase cytogenetics. By far the most frequent abnormality are deletions involving chromosome band 13q14, followed by deletions of the genomic region 11q22.3-q23.1, trisomy 12, deletions of 6q21-q23, and deletions/mutations of the TP53 tumor suppressor gene at 17p13. The evaluation of the true incidence of these aberrations now provides the basis for more accurate correlations with clinical characteristics and outcome. Deletions/mutations of the TP53 gene have been shown to be associated with resistance to treatment and to be an independent marker for poor survival. 11q deletions have been associated with extensive nodal involvement, rapid disease progression, and short survival times. Whether trisomy 12, 13q14, and 6q deletions have a prognostic impact awaits further study. The application of these molecular cytogenetic techniques will also contribute to the identification of the pathogenetically relevant genes that are affected by the chromosome aberrations in B-CLL.
276 citations
TL;DR: The identification of particular downstream targets of PKB has provided new insights into the possible mechanism of PI3K/PKB-mediated tumorigenicity and a subfamily of Forkhead transcription factors was identified as additional targets for PI3k/P KB signaling.
Abstract: The proto-oncogene protein kinase B (PKB), also known as c-Akt, is a central player in a signaling pathway of which many components have been linked to tumorigenesis. Active forms of PKB as well as of its upstream activator phosphatidylinositol 3-kinase (PI3K) have been found to be responsible for the transforming activities of certain viruses, and the negative regulator of this pathway, PTEN, is a tumor suppressor. The identification of particular downstream targets of PKB has provided us with new insights into the possible mechanism of PI3K/PKB-mediated tumorigenicity. Recently a subfamily of Forkhead transcription factors was identified as additional targets for PI3K/PKB signaling. This review discusses the studies that have led to this conclusion and the possible implications of this finding for our understanding of how PI3K/PKB activity could lead to oncogenesis.
274 citations
TL;DR: Therapeutic strategies aimed at ameliorating I/R damage are focused both on controlling ROS generated at the time of oxygen reperfusion and on intervening in the activated signal transduction cascades.
Abstract: Organ injury caused by transient ischemia followed by reperfusion is associated with a number of clinically and environmentally induced conditions. Ischemia/reperfusion (I/R) conditions arise during surgical interventions such as organ transplantation and coronary bypass surgery, and in diseases such as stroke and cardiac infarct. The destructive effects of I/R arise from the acute generation of reactive oxygen species subsequent to reoxygenation, which inflict direct tissue damage and initiate a cascade of deleterious cellular responses leading to inflammation, cell death, and organ failure. This review summarizes existing and potential approaches for treatment that have been developed from research using model systems of I/R injury. Although I/R injury in the liver is emphasized, other organ systems share similar pathophysiological mechanisms and therapeutic approaches. We also review current knowledge of the molecular events controlling cellular responses to I/R injury, such as activation of AP-1 and NF-κB pathways. Therapeutic strategies aimed at ameliorating I/R damage are focused both on controlling ROS generated at the time of oxygen reperfusion and on intervening in the activated signal transduction cascades. Potential therapies include pharmacological treatment with small molecules, antibodies to cytokines, or free-radical scavenging enzymes, such as superoxide dismutase or catalase. Additionally, the use of gene therapy approaches may significantly contribute to the development of strategies aimed at inhibiting of I/R injury.
234 citations
TL;DR: Analysis of two completed genome sequences from unrelated strains indicates that the H. pylori specific genes have a lower level of conservation than those orthologues to which a putative function can be assigned, and implies a need to reassess the respective roles of bacterial and host factors in H.pylori associated diseases.
Abstract: Infection with Helicobacter pylori has been linked to numerous severe gastroduodenal diseases including peptic ulcer and gastric cancer. Several techniques have been used to measure the genetic heterogeneity of H. pylori at several different levels and to determine whether there is any correlation with severity of disease. The availability of two completed genome sequences from unrelated strains (J99 and 26695) has allowed an analysis of the level of diversity from a large-scale yet detailed perspective. Although the two chromosomes are organized differently in a limited number of discrete regions, the genome size and gene order of these two "high-virulence" (cagA+ and vacA+) H. pylori isolates was found to be highly similar. The regions of organizational difference are associated with insertion sequences, DNA restriction/modification genes, repeat sequences, or a combination of the above. A significant level of variation at the nucleotide level is seen across the genome, providing an explanation for why the nucleotide-based typing techniques have such high discriminatory power among independent H. pylori isolates. This nucleotide variation together with the organizational rearrangements appears to have provided an over-estimation of the gene order diversity of H. pylori as assessed by pulse-field gel electrophoresis. Functional assignments are assigned to approximately only 60% of the gene products in each strain, with one-half of the remaining gene products of unknown function having homologues in other bacteria, while the remainder appear to be H. pylori-specific. Between 6% and 7% of the coding capacity of each strain are genes that are absent from the other strain, with almost one-half of these strain-specific genes located in a single hypervariable region called the plasticity zone. The majority of the strain-specific genes in each strain are also H. pylori-specific, with no homologues being identified in the public databases. Significantly, over one-half of the functionally assigned strain-specific genes in both H. pylori J99 and 26695 encode DNA restriction/modification enzymes. Analysis of the level of conservation between orthologues from the two strains indicates that the H. pylori specific genes have a lower level of conservation than those orthologues to which a putative function can be assigned. The plasticity zone represents one of several regions across each genome that is comprised of lower (G+C)% content DNA, some of which has been detected in self-replicating plasmids, suggesting that both horizontal transfer from other species and plasmid integration are responsible for the strain-specific diversity at this locus. These analyses have yielded results with important implications for understanding the genetic diversity of H. pylori and its associated diseases, and imply a need to reassess the respective roles of bacterial and host factors in H. pylori associated diseases.
194 citations
TL;DR: The expression/purification procedure is suitable for producing large amounts of highly pure sGC which contains one heme per heterodimer without a reconstitution step and the activator experiments show that in a synergistic stimulation with YC-1 sGC can be activated maximally both by nitric oxide and by carbon monoxide and that Yc-1 does not directly act via heme.
Abstract: Soluble guanylyl cyclase (sGC) is the main receptor for nitric oxide, a messenger molecule with multiple clinical implications. Understanding the activation of sGC is an important step for establishing new therapeutic principles. We have now overexpressed sGC in a baculovirus/Sf9 system optimized for high protein yields to facilitate spectral and kinetic studies of the activation mechanisms of this enzyme. It was expressed in a batch fermenter using a defined mixture of viruses encoding the α1 and β1 subunits of the rat lung enzyme. The expressed enzyme was purified from the cytosolic fraction by anion exchange chromatography, hydroxyapatite chromatography, and size exclusion chromatography. By use of this new method 2.5 l culture yielded about 1 mg of apparently homogeneous sGC with a content of about one heme per heterodimer without the need of a heme reconstitution step. The enzyme did not contain stoichiometric amounts of copper. The basal activities of the purified enzyme were 153 and 1259 nmol min–1 mg–1 in the presence of Mg2+ and Mn2+, respectively. The nitric oxide releasing agent 2-(N,N-diethylamino)-diazenolate-2-oxide (DEA/NO) stimulated the enzyme 160-fold with Mg2+, whereas the NO-independent activator 3-(5’-hydroxymethyl-2’-furyl)-1- benzylindazole (YC-1) induced an increase in the activity of 101-fold at a concentration of 300 µM. The combination of DEA/NO (10 µM) and YC-1 (100 µM) elicited a dose-dependent synergistic stimulation with a maximum of a 792-fold increase over the basal activity in the presence of Mg2+, resulting in a specific activity of 121 µmol min–1 mg–1. The synergistic stimulation of DEA/NO and YC-1 was attenuated by the sGC inhibitor 1H-(1,2,4)oxadiazole(4,3-a)quinoxalin-1-one (ODQ) (10 µM) by 94%. In a different experimental setup a saturated carbon monoxide solution in the absence of ambient oxygen or NO stimulated the enzyme 15-fold in the absence and 1260-fold in the presence of YC-1 compared to an argon control. The heme spectra of the enzyme showed a shift of the Soret peak from 432 to 399 and 424 nm in the presence of DEA/NO or carbon monoxide, respectively. The heme spectra were not affected by YC-1 in the absence or in the presence of DEA/NO or of carbon monoxide, which reflects the fact that YC-1 does not interact directly with the heme group of the enzyme. In summary, this study shows that our expression/purification procedure is suitable for producing large amounts of highly pure sGC which contains one heme per heterodimer without a reconstitution step. The activator experiments show that in a synergistic stimulation with YC-1 sGC can be activated maximally both by nitric oxide and by carbon monoxide and that YC-1 does not directly act via heme. The described method should help to facilitate the investigation of the new therapeutic principle of NO-independent guanylyl cyclase activators.
181 citations
TL;DR: The various subunits of human heart myosin in health and disease are described and their functions are discussed.
Abstract: Cardiac contraction is triggered by the cyclic interaction of the "molecular motor" protein myosin with the actin filament, consuming ATP as the energy source to produce tension or shortening. The myosin heavy chain (MHC) contains the actin- and ATP-binding sites and represents the molecular motor of muscle contraction. This review describes the various subunits of human heart myosin in health and disease and discusses their functions. Two different MHC genes (α and β) with distinct biochemical features are expressed in the human heart. α-MHC confers a higher ATPase activity and higher shortening velocity to the heart than β-MHC. Motor function is regulated by myosin light chain (MLC) isoforms. Expression of the atrial MLC-1 isoform in the hypertrophied human ventricle increases cross-bridge cycling and contractility. It is suggested that MLC-1 acts as a MHC/actin tether. Weakening of this tether increases myosin function. MLC-2 slows the rate of tension development of myosin. This relative inhibition is relieved upon phosphorylation of the MLC-2 perhaps caused by "swing-out" of cross-bridges from the myosin filament. Mutations in all ventricular myosin subunits have been found in patients with hypertrophic cardiomyopathy.
177 citations
TL;DR: Analysis of animal models revealed exciting new functions of lipoprotein receptors not only in systemic clearance of Lipoproteins but also in other important biological processes including reproduction, brain development, and adipositas.
Abstract: The low-density lipoprotein receptor gene family encompasses a class of endocytic receptors that exhibit structural similarities to the low-density lipoprotein receptor. Members of this gene family are present in both vertebrate and nonvertebrate species. The identification of naturally occurring mutations and the application of gene targeting to inactivate receptor genes enabled us to develop animal models to investigate the consequences of individual receptor defects in vivo. Analysis of these animal models revealed exciting new functions of lipoprotein receptors not only in systemic clearance of lipoproteins but also in other important biological processes including reproduction, brain development. and adipositas.
163 citations
TL;DR: Interestingly, cytokines in the brain and other stressors can also generate systemic immunodepression at the monocyte level and the catecholamine-induced release of the potent anti-inflammatory cytokine interleukin-10 is a newly discovered mechanism of the brain-mediated monocyte deactivation.
Abstract: Overwhelming inflammatory immune response can result in systemic inflammation and septic shock. To prevent excessive and deleterious action of proinflammatory cytokines after they have produced their initial beneficial effects, the immune system can release several anti-inflammatory mediators, including interleukin-10, interleukin-1 receptor antagonist, and soluble tumor necrosis factor receptors, thus initiating a compensatory anti-inflammatory response syndrome. However, in vivo the delicate balance between pro- and anti-inflammatory responses is additionally controlled by the central nervous system. Therefore, proinflammatory cytokines stimulate the hypothalamic-pituitary-adrenal axis and enhance sympathetic nerve system activity. The mediators of these neuroimmune pathways can again suppress immune cell functions to control systemic inflammation. The question is, however, what happens if the immunoinhibitory CNS pathways are activated without systemic inflammation? This can result from production of cytokines in the brain following infection, injury, or ischemia or in response to various stressors (e.g., life events, depression, anxiety) or directly from brainstem irritation. The answer is that this may generate a brain-mediated immunodepression. Many animal and clinical studies have demonstrated a stress and brain cytokine mediated decrease in the cellular immune response at the lymphocyte level. More recently, the importance of monocytes in systemic immunocapacity has been shown. Monocytic inactivation with decreased capability of antigen presentation and depressed secretion of proinflammatory cytokines increases the risk of infectious complications. Interestingly, cytokines in the brain and other stressors can also generate systemic immunodepression at the monocyte level. In this scenario the catecholamine-induced release of the potent anti-inflammatory cytokine interleukin-10 is a newly discovered mechanism of the brain-mediated monocyte deactivation in addition to the "well known" immunosuppressive action of glucocorticoids. Furthermore, other neuropeptides such as alpha-melanocyte-stimulating hormone and beta-endorphin which can be released in stressful situations have also inhibitory effects on immune cells. Thus mediators of the CNS are implicated in the regulation of immune functions and may play a role in both conditioning the host's response to endogenous or exogenous stimuli and generating a "brain-mediated" immunodepression.
TL;DR: The increasing knowledge about the mechanisms involved in beta cell differentiation and proliferation may lead to new ways of forming beta cells for treatment of diabetes in man.
Abstract: Formation of new beta cells can take place by two pathways: replication of already differentiated beta cells or neogenesis from putative islet stem cells. Under physiological conditions both processes are most pronounced during the fetal and neonatal development of the pancreas. In adulthood little increase in the beta cell number seems to occur. In pregnancy, however, a marked hyperplasia of the beta cells is observed both in rodents and man. Increased mitotic activity has been seen both in vivo and in vitro in islets exposed to placental lactogen (PL), prolactin (PRL) and growth hormone (GH). Receptors for both GH and PRL are expressed in islet cells and are upregulated during pregnancy. By mutational analysis we have identified different functional domains of the cytoplasmic part of the GH receptor. Thus the mitotic signaling only requires the membrane proximal part of the receptor and activation of the tyrosine kinase JAK2 and the transcription factors STAT1 and 3. The activation of the insulin gene however also requires the distal part of the receptor and activation of calcium uptake and STAT5. In order to identify putative autocrine growth factors or targets for growth factors we have cloned a novel GH/PRL stimulated rat islet gene product, Pref-1 (preadipocyte factor-1). This protein contains six EGF-like motifs and may play a role both in embryonic pancreas differentiation and in beta cell growth and function. In summary, the increasing knowledge about the mechanisms involved in beta cell differentiation and proliferation may lead to new ways of forming beta cells for treatment of diabetes in man.
TL;DR: In experimental models of heart failure bosentan acts as a vasodilator and neurohormonal blocker that improves overall left ventricular performance and reduces renal dysfunction, and in chronic studies, bosENTan attenuates cardiac remodeling and significantly improves survival.
Abstract: Endothelin receptor antagonists have been proposed for the treatment of a variety of disorders in which the endothelins may act as pathogenic mediators, such as congestive heart failure, systemic and pulmonary hypertension, and cerebral vasospasm. Bosentan (Ro 47-0203) is a nonpeptide competitive antagonist, which can be a good tool for studying the endothelin system because it may be administered either acutely or chronically. It is specific for the endothelin system and blocks the actions of endothelin at both mammalian receptors (A and B). In experimental models of heart failure bosentan acts as a vasodilator and neurohormonal blocker that improves overall left ventricular performance and reduces renal dysfunction. Furthermore, in chronic studies, bosentan attenuates cardiac remodeling and significantly improves survival. In patients with chronic heart failure bosentan produces pulmonary and systemic vasodilation and may enhance conventional treatment with angiotensin-converting enzyme inhibitors. Long-term studies are being conducted to characterize the full therapeutic potential of bosentan in chronic heart failure. In experimental models bosentan reverses established pulmonary hypertension. Preclinical efficacy has also been demonstrated in essential hypertension, where bosentan can reduce blood pressure and end-organ damage. Clinical trials in hypertensive patients indicate that bosentan reduces blood pressure without heart rate increase or neurohumoral stimulation. Finally, bosentan is being considered for the treatment of cerebral vasospasm following subarachnoid hemorrhage. Bosentan reverses experimentally induced vasospasm of the basilar artery, and preliminary trials indicate that it can increase cerebral blood flow after aneurysmal subarachnoid hemorrhage.
TL;DR: Results have been achieved with polylysine-alginate microencapsulated islet grafts in rodents, but clinical application is still restricted to a very small number of cases, and further studies should focus on finding a practically applicable method to reduce the barrier between encapsulation islets and the bloodstream, in order to improve both the functional performance and the survival of encapsulated islets grafts.
Abstract: There are several approaches of immunoprotection of pancreatic islets for the purpose of successful allo- or xenotransplantation in the absence of immunosuppressive medication. Extravascular approaches are either macroencapsulation (large numbers of islets together in one device) or microencapsulation. The latter approach is to envelop each individual islet in a semipermeable immunoprotective capsule. Quite promising results have been achieved with polylysine-alginate microencapsulated islet grafts in rodents, but clinical application is still restricted to a very small number of cases. Relevant considerations regard the following aspects. The biocompatibility of the microcapsules is influenced by the chemical composition of the materials applied and by mechanical factors related to the production process. With purified instead of crude alginates, the percentage of capsules with fibrotic overgrowth is reduced to approximately ten percent, and the remaining overgrowth is mainly explained by mechanical factors, i.e. inadequate encapsulation of individual islets. Even with purified alginates, however, the duration of encapsulated graft function is limited to a period of six to twenty weeks. Obviously, other factors than bioincompatibility play a role, which factors have to be identified. The limited duration of graft survival cannot be explained by rejection since, in rats, survival times of encapsulated isografts are similar, if not identical, to those of encapsulated allografts. An important factor is probably insufficient nutrition as a consequence of insufficient blood supply of the encapsulated and thus isolated islet. This also influences the functional performance of encapsulated islet grafts. Although normoglycemia can be readily obtained in streptozotocin diabetic rat recipients, glucose tolerance remains severely impaired, as a consequence of an insufficient increase of insulin levels in response to intravenous or oral glucose challenge. Important factors are the characteristics of the capsules applied in view of optimal diffusion kinetics, and the fact that an encapsulated islet graft can only be implanted in the peritoneal cavity because of its volume. Further studies should focus on finding a practically applicable method to reduce the barrier between encapsulated islets and the bloodstream, in order to improve both the functional performance and the survival of encapsulated islet grafts.
TL;DR: The conclusion is that the immunogenicity of tumor killing is determined by a combination of factors, including the mechanism of killing, the levels of cell death, the local environment that exists within the dying tumor and, as a result, the nature of the immune/scavenger cells which are present at the time of antigen release.
Abstract: Here we discuss how the mechanisms by which tumor cells are killed in vivo by gene transfer affects their immunogenicity. Our own work has shown that necrotic cell death induces immunological activation signals which recruit, load, activate and mature appropriate subsets of antigen-presenting cells. In contrast, for apoptotic cell death to be immunogenic, signals additional to cell death alone must be provided within the milieu of the dying tumor. Our conclusion is that the immunogenicity of tumor killing is determined by a combination of factors, including the mechanism of killing, the levels of cell death, the local environment that exists within the dying tumor and, as a result, the nature of the immune/scavenger cells which are present at the time of antigen release. Knowledge of how these factors can influence the immune system and lead to the breaking of tolerance to tumor-associated antigens, can potentially be exploited in the design of effective immunotherapies for cancer using gene transfer.
TL;DR: The Sonic Hedgehog/Patched/Smoothened signaling pathway is thus rapidly emerging as one of the most important regulators of oncogenic transformation and plays an important role during mammalian embryonic development.
Abstract: The identification of mutations in the human homolog of the Drosophila segment polarity gene Patched in basal cell carcinoma has sparked intense interest in the role of this gene in human disorders. The transmembrane protein Patched is a receptor for the morphogene Sonic Hedgehog. Sonic Hedgehog/Patched signaling involves another transmembrane protein, Smoothened, and its intracellular effectors, including the proto-oncogene GLI1. During the past 2 years it has become evident that mutations in Patched or in one of the components of its signaling pathway contribute to the formation of several common human tumors. It is now well established that Patched is a tumor suppressor gene. The Sonic Hedgehog/Patched/Smoothened signaling pathway is thus rapidly emerging as one of the most important regulators of oncogenic transformation. This pathway also plays an important role during mammalian embryonic development. This dual role is especially visible in humans with inherited Patched mutations. Such patients suffer from Gorlin, or nevoid basal cell carcinoma, syndrome and exhibit a variety of developmental defects accompanied by a predisposition to tumor formation. Activating mutations in Sonic Hedgehog and Smoothened lead to similar phenotypes as do loss-of function mutations in Patched. By means of transgenic and gene targeting technologies the respective mutations have been expressed in the mouse. Such mutant mouse strains exhibit many symptoms observed in humans. These strains are useful models to study the pathogenesis of several common human tumors and developmental defects. Furthermore they provide important tools to study the Sonic Hedgehog/Patched/Smoothened signaling at the molecular and biochemical level.
TL;DR: Comparison of the IRF-Smad alignment to the known three-dimensional structure of human tumor suppressor Smad4 suggests that a conserved loop, equivalent to Loop 3 in Smad 4, is a determinant of protein-protein interaction in IRFs.
Abstract: Interferon regulatory factors (IRFs) regulate the transcription of both interferon-inducible genes and interferons themselves. Along with the N-terminal, DNA-binding, winged-helix domain, most IRFs contain the C-terminal domains that are shown to be related to the C-terminal domains in the proteins of the Smad family that mediate transcription activation in the transforming growth factor response pathway. Comparison of the IRF-Smad alignment to the known three-dimensional structure of human tumor suppressor Smad4 suggests that a conserved loop, equivalent to Loop 3 in Smad 4, is a determinant of protein-protein interaction in IRFs.
TL;DR: Results obtained using highly sensitive polymerase chain reaction based detection methods and detailed immunological characterization of the inflammatory process associated with chagasic cardiomyopathy indicate a positive correlation between tissue parasitism and the severity of cardiac pathological findings, supporting the notion that the presence of the parasite is a necessary and sufficient condition for Chagas’ disease.
Abstract: Current developments in experimental chemotherapy of Chagas' disease are reviewed, in particular the demonstration that fourth-generation azole derivatives (inhibitors of sterol C14alpha demethylase), with particular selectivity against Trypanosoma cruzi and special pharmacokinetic properties, are capable of inducing radical parasitological cures in murine models of both acute and chronic disease. These are the first reports of parasitological cure of this disease in its chronic phase. We also discuss the relevance of etiological treatment in the clinical outcome of patients with chronic Chagas' disease. Although previous studies have suggested an important autoimmune component in the pathogenesis of this disease, recent results obtained using highly sensitive polymerase chain reaction based detection methods and detailed immunological characterization of the inflammatory process associated with chagasic cardiomyopathy indicate a positive correlation between tissue parasitism and the severity of cardiac pathological findings. Effective antiparasitic treatment can lead to regression of the inflammatory heart lesions and fibrosis in experimental animals and to stop the progression of the disease in humans. Taken together, these findings support the notion that the presence of the parasite is a necessary and sufficient condition for chagasic cardiomyopathy and confirm the importance of specific etiological treatment in the management of chronic chagasic patients.
TL;DR: The eNOS Glu-298→Asp mutation is common, occurring with an allele frequency of 32.5%, but is not associated with either the occurrence or severity of CAD in the Australian population or with other established coronary risk factors assessed in this study.
Abstract: We examined associations between the endothelial nitric oxide synthase (eNOS) gene Glu-298→Asp (894G→T) mutation and the occurrence and severity of angiographically defined coronary artery disease (CAD). eNOS mediates basal vascular wall nitric oxide production, and altered nitric oxide production has been implicated in atherosclerosis. The newly identified eNOS Glu-298→Asp mutation in exon 7 is common and likely to be functional. It was found to be associated with myocardial infarction (MI) in Japanese but not in whites. We genotyped 763 white Australians undergoing coronary angiography for the eNOS Glu-298→Asp mutation. The frequencies of the eNOS GG, TG and TT genotypes were 47.8%, 41.2% and 11.0% in men and 45.2%, 41.1% and 13.7% in women with CAD, and were not significantly different from those without CAD (43.2%, 40.7% and 16.0%, P=0.423 in men; 40.2%, 48.1% and 11.7%, P=0.582 in women). The mutation was also not associated with MI (P=0.469 in males; P=0.389 in females) or with the number of significantly stenosed vessels (P=0.954; P=0.734). The "T" allele frequency (32.5%) was much greater than that reported for the Japanese population (7.8% in controls and 10.0% in MI patients). In conclusion, the eNOS Glu-298→Asp mutation is common, occurring with an allele frequency of 32.5%, but is not associated with either the occurrence or severity of CAD in the Australian population or with other established coronary risk factors assessed in our study. The mutation is significantly more frequent in the Australian than in the Japanese.
TL;DR: This contribution reviews the Ang II induced ITF expression in various tissues and discusses the possible physiological and pathophysiological consequences of the resulting changes in genetic patterns.
Abstract: Transcription factors are DNA-binding proteins which are able to identify specific nucleotide sequences and by binding to them may regulate the expression of genes at the level of transcription. In addition to the general transcription factors, which are basically the same for each gene transcribed by eukaryotic RNA polymerase II, more than 100 specific transcription factors have been identified so far. These specific transcription factors regulate the expression patterns of various sets of inducible genes during growth and development and enable the adjustment of cells and tissues to environmental changes. Especially the AP-1 proteins have found increasing interest, since members of these families such as c-Fos and c-Jun seem to be involved in trophic changes in peripheral organs. Many studies have also used them as marker proteins for activated neurons in the central nervous system to identify functional pathways and connections between brain nuclei. The renin-angiotensin system is implicated both in the hormonal and the central regulation of blood pressure and volume homeostasis. By binding to their specific receptors angiotensin peptides, namely angiotensin (Ang) II, have also been reported to induce the expression of a variety of inducible transcription factors (ITF) of the AP-1 and other families in peripheral organs such as kidney and blood vessels and in specific brain regions. By activating ITF, transient ligand receptor signals are transformed into long-lasting genetic changes. While the Ang II induced expression of ITF in peripheral organs seems to be associated with trophism, the physiological significance of this expression in brain nuclei with their postmitotic cells is much less clear. This contribution reviews the Ang II induced ITF expression in various tissues and discusses the possible physiological and pathophysiological consequences of the resulting changes in genetic patterns.
TL;DR: This review discusses frequent alterations concerning proliferative, differentiation-inducing, and apoptotic pathways elucidated in the recent years that have improved the understanding of this disease.
Abstract: Chronic lymphocytic leukemia is a malignant disease characterized by clonal expansion of relatively mature B-lymphocytes with a high percentage of cells arrested in the nonproliferative G0/G1 cell cycle phase. Possibly reflecting the clinical heterogeneity observed in patients, various signaling pathways may become affected during the initiation and course of this disease. This review discusses frequent alterations concerning proliferative, differentiation-inducing, and apoptotic pathways elucidated in the recent years that have improved our understanding of this disease.
TL;DR: These results provide for the first time convincing evidence that ANG II upregulates TGF-β receptor type II expression on proximal tubular cells.
Abstract: Tubulointerstitial fibrosis is a common end-point of many chronic renal diseases and contributes to the permanent loss of renal function. There is increasing evidence that the profibrogenic cytokine transforming growth factor TGF) β plays an essential role in this process by inducing the production of extracellular matrix proteins by tubular cells through an autocrine mechanism. We have previously demonstrated that the vasopeptide angiotensin (ANG) II induces TGF-β transcription and synthesis in cultured murine proximal tubular cells (MCT cell line). Since the overall effects of TGF-β on a distinct target cell may also depend on the expression of specific cell surface receptors, the present study was undertaken to test the hypothesis that ANG II modulates expression of TGF-β receptors in MCT cells. ANG II stimulated protein expression of TGF-β receptor type II, but not that of type I, in MCT cells as detected by immunofluorescence and western blotting of cell lysates. This stimulated receptor expression was also reflected in an overall increase in specific binding of 125I-labeled TGF-β1 to intact MCT cells. Coincubation with ANG II and an AT1 receptor antagonist abolished this increase in 125I-labeled TGF-β1 binding. Furthermore, ANG II also increased steady-state mRNA expression for TGF-β receptor type II. This stimulation was transduced through AT1 receptors and was independent of TGF-β released into the culture medium. Transient transfection studies using various length enhancer/promoter elements of the human TGF-β receptor type II linked to the CAT gene revealed that AP1 sites are a necessary prerequisite for ANG II induced transcriptional activity. ANG II had no effect on TGF-β receptor types I or II protein or on mRNA expression in syngeneic mesangial cells. Our results provide for the first time convincing evidence that ANG II upregulates TGF-β receptor type II expression on proximal tubular cells. Since this subtype of receptor is primarily engaged in the initial binding of TGF-β, an increased receptor expression may result in amplification of the TGF-β effects on tubular cells. Interference with an activated renin-angiotensin system could therefore counteract the profibrogenic effects of TGF-β by abolishing ANG II induced expression of TGF-β receptor type II.
TL;DR: Compounds with the ability to prevent and to reverse protein conformational changes may be useful as novel therapeutic approaches for Alzheimer’s disease, prion disease, and other disorders of defective protein folding.
Abstract: Several lines of evidence suggest that a defective protein folding is a central event in both Alzheimer’s and prion disease. Although the two disorders are very different clinically, neuropathologically, and biochemically, the molecular event that may trigger the disease process appears to be the same: the formation of an altered protein conformer composed of a high content of β-sheet structure. Compounds with the ability to prevent and to reverse protein conformational changes may be useful as novel therapeutic approaches for Alzheimer’s disease, prion disease, and other disorders of defective protein folding.
TL;DR: In one study, insulin independence was achieved in spontaneously diabetic dogs by islet microencapsulation inside uncoated alginate gel spheres (Mr exclusion >600 kD), and data from the laboratory in rodents and dogs indicate that these systems can function for extended periods of time.
Abstract: Studies involving the transplantation of human islets in Type I diabetics have been of significant value both in documenting the potential importance of islet transplantation as a therapeutic modality, and in defining some of the problems which must be overcome before this approach can be used in large numbers of patients. The currently limited supply of adult human pancreatic glands, and the fact that chronic immunosuppression is required to successfully transplant islets into patients, indicate that techniques must be further developed and refined for allo- and xenografting of isolated islets from human and animal sources to diabetic patients. An increasing body of evidence using microencapsulation techniques strongly suggests that this will be achieved during the next few years. Data from our laboratory in rodents and dogs indicate that these systems can function for extended periods of time. In one study, insulin independence was achieved in spontaneously diabetic dogs by islet microencapsulation inside uncoated alginate gel spheres (Mr exclusion >600 kD). No synthetic materials or membrane coatings were employed in this study. Spheres containing canine islets were implanted into the peritoneum of 4 diabetic dogs. The animals received low-dose CsA (levels below readable limits by HPLC at 3 weeks). Implantation of these spheres completely supplanted exogenous insulin therapy in the dogs for 60 to >175 days. Blood glucose concentration averaged 122+/-4 mg/dl for these animals during the first 2 months. The glycosylated hemoglobin (HbAIC) levels during this period dropped from 6.7+/-0.5% to 4.2+/-0.2% (P<0.001). IVGTT K-values at 1 and 2 months postimplantation were 1.6+/-0.1 (P<0.002) and 1.9+/-0.1 (P<0.001), respectively compared with 0.71+/-0.3 before implantation. In a second group of studies, bovine islets were immobilized inside a new type of selectively permeable "microreactor" (Mr exclusion <150 kD) and implanted into the peritoneum of 33 STZ-induced diabetic rats without any immunosuppression. Diabetes was promptly reversed, and normoglycemia maintained for periods of several weeks to months. Immunohistochemical staining of microreactors recovered from these animals revealed well-granulated beta-cells consistent with functionally active insulin synthesis and secretion. To test further the secretory function of the islets, some of the explanted microreactors were incubated in media containing either basal or stimulatory concentrations of glucose. The islets responded with an approximately 3- to 5-fold average increase above basal insulin secretion. These results are encouraging, and may have important implications in assessing the potential role of these microencapsulation systems as therapy for human insulin-dependent diabetes.
TL;DR: As an antioxidant melatonin would appear to provide substantial protection against free radicals which are generated under a variety of experimental corrections, including ischemia/reperfusion injury.
Abstract: Melatonin, a molecule synthesized and secreted by the mammalian (including human) pineal gland, has a variety of seemingly unrelated functions in organisms. In photoperiodically-dependent seasonal breeders, the changing melatonin signal imparts seasonal information to the species thereby regulating the annual cycle of reproduction [1]. Melatonin also is involved in a number of 24 h rhythms and is believed to be an important component of the circadian system [2, 3]. More recently, melatonin was found to relate to immune function [4] in organisms and to be an effective antioxidant [5]. As an antioxidant melatonin would appear to provide substantial protection against free radicals which are generated under a variety of experimental corrections, including ischemia/reperfusion injury [6, 7]. These latter two functions of melatonin, i.e., as an immune system modulator and as an antioxidant, both may have applicability to cell and organ transplantation [8–11].
TL;DR: The development of immune cell therapies in which the injured CNS is exogenously provided with an adequate number of appropriately activated immune cells (macrophages for regrowth and autoimmune T cells for maintenance), controlled in such a way as to derive maximal benefit with minimal risk of disease is proposed.
Abstract: The irreversible loss of function after axonal injury in the central nervous system (CNS) is a result of the lack of neurogenesis, poor regeneration, and the spread of damage caused by toxicity emanating from the degenerating axons to uninjured neurons in the vicinity. Now, 100 years after Ramon y Cajal's discovery that CNS neurons--unlike neurons of the peripheral nervous system--fail to regenerate, it has become evident that (a) CNS tissue is indeed capable of regenerating, at.least in part, provided that it acquires the appropriate conditions for growth support, and (b) that the spread of damage can be stopped and the postinjury rescue of neurons thus achieved, if ways are found to neutralize the mediators of toxicity, either by inhibiting their action or by increasing tissue resistance to them. In most physiological systems the processes of tissue maintenance and repair depend on the active assistance of immune cells. In the CNS, however, communication with the immune system is restricted. The accumulated evidence from our previous studies suggests that the poor posttraumatic repair and maintenance in the CNS is due at least in part to this restriction. Key factors in the recovery of injured tissues, but missing or deficient in the CNS, are the processes of recruitment and activation of immune cells. We therefore propose the development of immune cell therapies in which the injured CNS is exogenously provided with an adequate number of appropriately activated immune cells (macrophages for regrowth and autoimmune T cells for maintenance), controlled in such a way as to derive maximal benefit with minimal risk of disease. It is expected that these self-adjusting cells will communicate with the damaged tissue, monitor tissue needs, and control the dynamic course of CNS healing.
TL;DR: Observations indicate that genetic modification of insulin-secreting cells by electrofusion (or transfection with cDNA) offers a new avenue for generation of useful clonal glucose-responsive pancreatic B-cell lines for studies of insulin secretion and transplantation in insulin-dependent diabetes mellitus.
Abstract: Despite many triumphs, a significant limitation of the usefulness of many of the available B-cell lines for the study of insulin secretion are either inappropriate or lack of responsiveness to glucose. Commonly employed cell lines generated prior to the 1990s following X-ray irradiation (RINm5F cells) or simian virus 40 B-cell transformation (HIT-T15 cells and BTC) fall into this category. More recent success has been achieved with the generation of INS-1 cells and MIN6 cells, but the production of these cell lines owes much to good fortune, dedication and hard work. In the present era, molecular biology techniques provide the opportunity to engineer novel pancreatic B-cell lines which possess many attributes of normal insulin-secreting cells. This review describes the electrofusion of normal NEDH rat pancreatic B-cells with immortal RINm5F cells to create three new glucose-responsive clonal insulin-secreting cells, designated BRIN-BG5, BRIN-BG7 and BRIN-BD11. These cell lines exhibit up to four-fold insulin-secretory responses to depolarization with 25 mmol/l K+, 7.68 mmol/l Ca2+, 10 mmol/l L-alanine, and activation of protein kinase C or adenylate cyclase with 10 nmol/l phorbol- 12-myristate-13-acetate or 25 micromol/l forskolin, respectively. The maximal insulin-secretory response of both BRIN-BG5 and BRIN-BG7 cells to glucose occurred at 8.4 mmol/l (1.9- and 1.8-fold increases, respectively). In contrast, 4.2-16.7 mmol/l glucose evoked a stepwise 2- to 3-fold of insulin release from BRIN-BD11 cells. The superior glucose responsiveness of BRIN-BD11 cells compared with BRIN-BG5 or BRIN-BG7 cells was associated with increased expression of GLUT-2 and a greater contribution of glucokinase to total glucose phosphorylating enzyme activity. Furthermore, BRIN-BD11 cells also showed appropriate responses to a diverse range of modulators of pancreatic B-cell function, including amino acids, neurotransmitters and sulphonylurea drugs. Collectively these observations indicate that genetic modification of insulin-secreting cells by electrofusion (or transfection with cDNA) offers a new avenue for generation of useful clonal glucose-responsive pancreatic B-cell lines for studies of insulin secretion and transplantation in insulin-dependent diabetes mellitus.
TL;DR: This review summarizes the current status of tumor antigens and their potential applications to cancer treatment and develops new opportunities for the development of therapeutic strategies against cancer.
Abstract: The adoptive transfer of tumor-infiltrating lymphocytes along with interleukin 2 into autologous patients resulted in the objective regression of tumor in about 30% of patients with melanoma, indicating that these T cells play a role in tumor rejection. To understand the molecular basis of the T cell-cancer cell interaction we and others started to search for tumor antigens expressed on cancer cells recognized by T cells. This led to the identification of several major histocompatibility complex (MHC) class I restricted tumor antigens. These tumor antigens have been classified into several categories: tissue-specific differentiation antigens, tumor-specific shared antigens, and tumor-specific unique antigens. Because CD4+ T cells play a central role in orchestrating the host immune response against cancer, infectious diseases, and autoimmune diseases, a novel genetic approach has recently been developed to identify these MHC class II restricted tumor antigens. The identification of both MHC class I and II restricted tumor antigens provides new opportunities for the development of therapeutic strategies against cancer. This review summarizes the current status of tumor antigens and their potential applications to cancer treatment.
TL;DR: An overview of the impact of DNA chip technology on the field of molecular medicine is presented and developments that can be expected in the near future are discussed.
Abstract: The recent popularity of DNA chip technology has been fostered by the increasing demand for new diagnostic tools which allow the simultaneous analysis of large numbers of nucleic acid hybridization experiments in a timely fashion. The development of DNA chip-based assays has been strongly driven by modern approaches aiming at the comprehensive analysis of multiple gene mutations and expressed sequences. The broad range of current DNA chip applications include the detection of pathogens, the measurement of differences in the expression of genes between different cell populations, and the analysis of genomic alterations such as sequence and copy number alterations in disease-related genes and single nucleotide polymorphisms. We present an overview of the impact of DNA chip technology on the field of molecular medicine and discuss developments that can be expected in the near future.