The murine monoclonal antibody BU31 binds to the nuclear membrane of many cell types. The expression of the BU31 antigen has previously been shown to have an inverse correlation with the proliferative index in lung tumours, defined by Ki67 staining. The distribution of BU31-positive cells is now shown to parallel the distribution of non-dividing cells in a range of normal human and rat tissues, although neuroendocrine cells and germ cells in the testis show no reactivity. Cells grown in culture and induced to undergo growth arrest show a higher level of labelling with BU31 than their proliferating counterparts. Confocal laser scanning microscopy reveals that the BU31 antigen is distributed predominantly along the nuclear lamina, with occasional internal foci. This distribution is very similar to that of the nuclear membrane proteins lamin A and lamin C, suggesting that the BU31 antigen and lamins A and C could be one and the same. Immunoblotting using recombinant lamin proteins confirmed this proposal. Moreover, a monoclonal antibody to the non-proliferation-associated antigen, statin, also recognizes lamins A and C. These data indicate that the demonstration of lamins A and C can be used to provide information on the proliferative activity of normal and neoplastic tissues. These data also suggest a role for nuclear lamins A and C during cellular quiescence, possibly through the reorganization and maintenance of nuclear structure, or more directly through interactions with the retinoblastoma gene product or related proteins.
Abstract The production of the murine monoclonal antibody BU31 is described. This antibody identifies a nuclear envelope protein which is expressed in some but not all cells, and which resembles statin, a protein reported to be expressed by non‐proliferating cells. BU31 was applied onto frozen sections of a series of 78 lung tumours and the staining patterns were compared with those obtained with Ki‐67. There was an inverse correlation between the proportion of tumour nuclei labelled with the two reagents (r= −0.61, 95 per cent confidence intervals −0.73 to −0.45). However, the four neuroendocrine neoplasms were BU31‐negative. Squamous cell carcinomas often showed a peripheral distribution of the cells stained positively with Ki‐67, whereas BU31 tended to label centrally situated cells. These observations are consistent with the concept that the antigen recognized by BU31 is expressed by non‐proliferating cells in these tumours.
The possibility that proliferating cell nuclear antigen (PCNA) is expressed by non-proliferating liver cells was investigated. Liver biopsies from 107 patients were investigated, which included histologically normal liver, metastatic tumour, and inflammatory lesions. PCNA was detected using immunohistochemical staining with the monoclonal antibody PC10. This was compared with the proportion of proliferating cells as assessed by immunostaining for the Ki-67 antigen using the monoclonal antibody MIB 1. Most cases of histologically normal liver showed few PC10-positive cells. PCNA-positive hepatocytes far outnumbered those positive with MIB 1 in specimens showing metastatic tumour or an inflammatory cell infiltrate. There was no relation between the degree of PCNA overexpression and the type of tumour present or the nature of the inflammatory lesion. Other cell types, including the biliary epithelium, did not show this large difference between the proportions of PC10- and MIB 1-positive cells. It is concluded that non-proliferating hepatocytes increase their levels of PCNA in a wide variety of pathological conditions. This may be mediated by cytokines released by tumour cells or inflammatory cells.
Intravenous targeting of anticancer agents should improve both efficacy and therapeutic index. However, rational design of targeting constructs requires detailed definition of receptor targets and must take account of polarised tissue architecture that may restrict access to chosen receptors from the bloodstream. Bacteriophage biopanning provides a solution to this problem, identifying targeting sequences by functional selection rather than design, although reiterative panning in polarized human tumours has not previously been attempted. Here, we report an ex vivo, intra-arterial method for biopanning in freshly-resected human tumours, enabling reiterative selection of oligopeptide sequences capable of intravascular targeting to human colorectal tumours. Significant consensus was observed after two rounds of panning in tumours from different patients, and lead sequences demonstrated tumour targeting in samples from unrelated patients. This novel approach may be applicable to a wide range of settings, thus enabling iteration of consensus targeting sequences for tumour imaging and selective delivery of anticancer agents.
Abstract Recent work has shown that p53 gene mutations are frequently found in Epstein‐Barr virus (EBV)‐positive and EBV‐negative cases of Burkitt's lymphoma but not in EBV‐associated undifferentiated nasopharyngeal carcinomas (NPCs). Similar viral gene expression patterns are observed in undifferentiated NPCs and in EBV‐positive cases of Hodgkin's disease (HD), suggesting that the contribution of the virus to the pathogenesis of these malignancies may also be similar. We have analysed 116 cases of HD for EBV association and for immunohistologically detectable overexpression of p53. p53 overexpression was detected in the tumour cell population of 37 (32 per cent) of the cases. Fifteen cases showed p53‐specific labelling of more than 40 per cent of tumour cells; in six of these, virtually all tumour cells were stained. In eight cases, between 5 and 40 per cent of tumour cells were labelled, and in another 14 cases, less than 5 per cent of tumour cells expressed detectable amounts of p53. EBV‐positive HD cases were found in all groups with different levels of p53 overexpression as well as amongst p53‐negative cases. While a more detailed analysis of the p53 gene in HD is required, these data show that overexpression of p53 in HD is heterogeneous and that there is no simple correlation between EBV infection and p53 overexpression.
Stathmin is a cytosolic phosphoprotein that has an important but, as yet, undefined role in cell proliferation and differentiation. Induction of growth arrest and differentiation of HL60 cells to monocytes by phorbol 12‐myristate 13‐acetate is associated with rapid phosphorylation of the protein. Stathmin phosphorylation was not seen when HL60 cells were induced to differentiate to monocytes, by 1α,25‐dihydroxyvitamin D3, and to neutrophils, by all‐trans retinoic acid and granulocyte colony stimulating factor. In all the above instances, stathmin expression was down‐regulated. Thus, increased stathmin phosphorylation is not required for cell growth arrest or differentiation or down‐regulation of stathmin expression.
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