John Radcliffe Hospital

About: John Radcliffe Hospital is a healthcare organization based out in Oxford, Oxfordshire, United Kingdom. It is known for research contribution in the topics: Population & Antigen. The organization has 14491 authors who have published 23670 publications receiving 1459015 citations.

Macrophage responses to hypoxia: relevance to disease mechanisms.

Abstract: Macrophages are ubiquitous in the stromal compartment of tissues under normal physiological conditions and the number of these cells increases markedly with the onset and progression of many pathological states. The mechanisms underlying this response are well described in such conditions as wound healing and malignant tumors, where tissue-specific signals enhance the extravasation of blood monocytes and their subsequent differentiation into macrophages. Recent evidence suggests that macrophages may also be stimulated by microenvironmental factors present in diseased tissues to perform distinct, tissue-specific activities. One such factor, hypoxia (low oxygen tension), results from insufficient vascular perfusion of a given tissue. Various studies have shown that experimental hypoxia alters the morphology, expression of cell surface markers, viability, phagocytosis, metabolic activity, and release of cytokines by macrophages. Here we review the evidence for these macrophage responses to hypoxia, the involvement of co-stimuli, and their implications for the role of macrophages in various disease processes. Because the intracellular mechanisms mediating the effects of hypoxia on gene expression in other cell types have been characterized recently, we discuss their possible involvement in the effects of hypoxia on gene expression in macrophages.

The structure-specific endonuclease Mus81 contributes to replication restart by generating double-strand DNA breaks.

Abstract: Faithful duplication of the genome requires structure-specific endonucleases such as the RuvABC complex in Escherichia coli. These enzymes help to resolve problems at replication forks that have been disrupted by DNA damage in the template. Much less is known about the identities of these enzymes in mammalian cells. Mus81 is the catalytic component of a eukaryotic structure-specific endonuclease that preferentially cleaves branched DNA substrates reminiscent of replication and recombination intermediates. Here we explore the mechanisms by which Mus81 maintains chromosomal stability. We found that Mus81 is involved in the formation of double-strand DNA breaks in response to the inhibition of replication. Moreover, in the absence of chromosome processing by Mus81, recovery of stalled DNA replication forks is attenuated and chromosomal aberrations arise. We suggest that Mus81 suppresses chromosomal instability by converting potentially detrimental replication-associated DNA structures into intermediates that are more amenable to DNA repair.

Viral infection and iron metabolism.

Abstract: Fundamental cellular operations, including DNA synthesis and the generation of ATP, require iron. Viruses hijack cells in order to replicate, and efficient replication needs an iron-replete host. Some viruses selectively infect iron-acquiring cells by binding to transferrin receptor 1 during cell entry. Other viruses alter the expression of proteins involved in iron homeostasis, such as HFE and hepcidin. In HIV-1 and hepatitis C virus infections, iron overload is associated with poor prognosis and could be partly caused by the viruses themselves. Understanding how iron metabolism and viral infection interact might suggest new methods to control disease.

The ageing lens and cataract: a model of normal and pathological ageing

Abstract: Cataract is a visible opacity in the lens substance, which, when located on the visual axis, leads to visual loss. Age-related cataract is a cause of blindness on a global scale involving genetic and environmental influences. With ageing, lens proteins undergo non-enzymatic, post-translational modification and the accumulation of fluorescent chromophores, increasing susceptibility to oxidation and cross-linking and increased light-scatter. Because the human lens grows throughout life, the lens core is exposed for a longer period to such influences and the risk of oxidative damage increases in the fourth decade when a barrier to the transport of glutathione forms around the lens nucleus. Consequently, as the lens ages, its transparency falls and the nucleus becomes more rigid, resisting the change in shape necessary for accommodation. This is the basis of presbyopia. In some individuals, the steady accumulation of chromophores and complex, insoluble crystallin aggregates in the lens nucleus leads to the formation of a brown nuclear cataract. The process is homogeneous and the affected lens fibres retain their gross morphology. Cortical opacities are due to changes in membrane permeability and enzyme function and shear-stress damage to lens fibres with continued accommodative effort. Unlike nuclear cataract, progression is intermittent, stepwise and non-uniform.

Identification of Hodgkin and Sternberg-reed cells as a unique cell type derived from a newly-detected small-cell population

Abstract: In this study the antigenic profile of Hodgkin (H) and Sternberg-Reed (SR) cells from cases of Hodgkin's disease was analysed using a large panel of monoclonal and polyclonal antibodies reactive with cells of lymphoid and haemotopoietic origin. The aim of this investigation was, firstly, to throw light on the origin of H and SR cells and, secondly, to determine whether there is any evidence to support recent suggestions that H and SR cells differ antigenically between different histological categories of Hodgkin's disease. Frozen sections (from 24 cases) and paraffin sections (83 cases) were stained by immunoenzymatic methods and the results compared with those obtained from staining a wide variety of reactive and neoplastic tissue samples (including examples of tuberculosis, sarcoidosis, malignant histiocytosis, histiocytosis X, osteomyelosclerosis and non-Hodgkin's lymphoma). The results revealed that H and SR cells of all types of Hodgkin's disease consistently lack markers found on null cells, B cells, T cells, cells of monocyte/macrophage series, interdigitating reticulum cells, dendritic reticulum cells and erythropoietic and thrombopoietic cells. However, H and SR cells constantly expressed an antigen detectable with the recently produced monoclonal antibody Ki-I. The vast majority of typical and lacunar type H and SR cells contained the granulocyte-related antigens detected by monoclonal antibodies TU5, TU6, TU9 and 3C4, whereas other more or less specific granulopoietic cell markers (such as peroxidase, chloroacetate esterade, lysozyme, cationic leukocyte antigen and OKMI) were consistently absent. H and SR cells in cases of nodular paragranuloma (nodular type of Hodgkin's disease with lymphocyte predominance) were not monotypic in light chain type (as has been previously reported), but rather contained chi and lambda chains within the same cells, as do typical and lacunar type H and SR cells. Immunostaining of normal and hyperplastic lymphoid tissue with the Ki-I antibody led to the detection of a new, as yet unidentified, small-cell population of unknown origin and function, which is present between, around, and within cortical follicles. It is concluded from these findings that H and SR cells constitute a unique cell type that differs in many properties from all other known cell types. Furthermore, H and SR cells of the various histological types of Hodgkin's disease are more closely related than previously believed. It is suggested that the hitherto unknown cell population detected with the monoclonal antibody Ki-I in normal lymphoid tissue is the normal equivalent of H and SR cells.