Fine-needle aspiration biopsy and flow cytometry immunophenotyping of lymphoid and myeloproliferative disorders of the spleen.

BACKGROUND: Flow cytometry (FC) is a useful adjunct to fine-needle aspiration biopsy (FNAB) in the evaluation of lymphoproliferative disorders. The application of FC to FNAB of the spleen (sFNAB) is reported. METHODS: Flow cytometry was performed on 18 sFNAB collected over 3 years. The series comprised 10 cases of non- Hodgkin lymphomas (NHL), 2 cases insufficient for diagnosis, 2 cases of reactive hyperplasia (RH), and 4 cases of myeloid metaplasia (MM). FNAB was performed under ultrasound guidance using a 22-gauge needle. One or two passes were sufficient to prepare a conventional smear that was immediately evaluated to select the cases studied and to prepare a cell suspension for FC. The following fluoresceinated antibodies were used: CD3, CD19/kappa/lambda, FMC7/CD23/CD19, Bcl-2, and CD13/HLA-DR. In six cases, cytospins were also prepared for immunocytochemistry and were tested for CD20 (L26), CD45Ro, and kappa and lambda light chain expression. RESULTS: Flow cytometry contributed to the diagnosis of all cases of NHL by assessing light chain restriction. The specific subtype was also diagnosed by CD19/CD5 and CD 19/CD10 coexpression in two cases. Flow cytometry quantified the percentage of myeloid cells in MM cases and contributed to the cytologic diagnosis showing a polyclonal light chain expression in RH cases.Immunocytochemistry was effective and concordant in four cases. Patients tolerated the sFNAB well and no complications were reported. Cytologic and FC diagnoses were confirmed by follow-up and by histologic evaluation in cases in which splenectomy was performed for therapeutic purposes. CONCLUSION: Flow cytometry applied to sFNAB corroborates the cytologic diagnosis in lymphoid and myeloproliferative disorders of the spleen and allows therapeutic decisions avoiding splenectomy

p27(Kip1 )is expressed in proliferating cells in its form phosphorylated on threonine 187

BACKGROUND: G1/S cell cycle progression requires p27(Kip1 )(p27) proteolysis, which is triggered by its phosphorylation on threonine (Thr) 187. Since its levels are abundant in quiescent and scarce in cycling cells, p27 is an approved marker for quiescent cells, extensively used in histopathology and cancer research. METHODS: However here we showed that by using a specific phosphorylation site (pThr187) antibody, p27 is detectable also in proliferative compartments of normal, dysplastic and neoplastic tissues. RESULTS: In fact, whereas un-phosphorylated p27 and MIB-1 showed a significant inverse correlation (Spearman R = -0.55; p < 0,001), pThr187-p27 was positively and significantly correlated with MIB-1 expression (Spearman R = 0.88; p < 0,001). Thus proliferating cells only stain for pThr187-p27, whereas they are un-reactive with the regular p27 antibodies. However increasing the sensitivity of the immunocytochemistry (ICH) by the use of an ultra sensitive detection system based on tiramide signal amplification, simultaneous expression and colocalisation of both forms of p27 was shown in proliferating compartments nuclei by double immunofluorescence and laser scanning confocal microscopy studies. CONCLUSION: Overall, our data suggest that p27 expression also occurs in proliferating cells compartments and the combined use of both regular and phospho- p27 antibodies is suggested

UbcH10 overexpression may represent a marker of anaplastic thyroid carcinomas

The hybridisation of an Affymetrix HG_U95Av2 oligonucleotide array with RNAs extracted from six human thyroid carcinoma cell lines and a normal human thyroid primary cell culture led us to the identification of the UbcH10 gene that was upregulated by 150-fold in all of the carcinoma cell lines in comparison to the primary culture cells of human normal thyroid origin. Immunohistochemical studies performed on paraffin-embedded tissue sections showed abundant UbcH10 levels in thyroid anaplastic carcinoma samples, whereas no detectable UbcH10 expression was observed in normal thyroid tissues, in adenomas and goiters. Papillary and follicular carcinomas were only weakly positive. These results were further confirmed by RT–PCR and Western blot analyses. The block of UbcH10 protein synthesis induced by RNA interference significantly reduced the growth rate of thyroid carcinoma cell lines. Taken together, these results would indicate that UbcH10 overexpression is involved in thyroid cell proliferation, and may represent a marker of thyroid anaplastic carcinomas