Paraneoplastic syndromes: Definitions, classification, pathophysiology and principles of treatment.

Paraneoplastic syndromes (PNS) are rare clinical syndromes due to the systemic effects of tumours; they are unrelated to tumour size, invasiveness or metastases. Recent years have seen considerable advances leading to improved understanding of their pathophysiology and increased recognition of new PNS entities and PNS associated tumours. While of paramount importance, diagnosis is still frequently missed or delayed. Diverse organs and systems are affected by the associated tumours- which may be benign or malignant. PNS can occur concurrently with tumour diagnosis, before tumour is diagnosed and even after tumours have been resected. Also, there are autoimmune diseases later progressing to PNS when occult tumours are identified. Another confounding factor is that many PNS clinically resemble non-neoplastic diseases. PNS are largely due to two main causes: those due to tumour secretions of hormones, functionally active peptides, enzymes cytokines or to tumours operating through auto-immune/immunological mechanisms with cross-reacting antibodies between neoplastic and normal tissues. Remission of symptoms often follows resection of humoral secretory tumours but not always of tumours due to immunological mechanisms. Classifications schemes vary but most currently place PNS in one of five groups: endocrine, neurological, musculocutaneous, haematological and other. Due to advances both in diagnostic techniques in identifying tumours as well as in therapy, early diagnosis not only results in improved prognosis of both PNS and associated tumours but also enables monitoring response to treatment and early detection of recurrence. This article covers definition, general principals of classification, diagnosis, pathophysiology and treatment, with emphasis on tumour related PNS serving as an introduction to the following articles.

Detection of human herpesvirus DNA in Kikuchi-Fujimoto disease and reactive lymphoid hyperplasia.

Kikuchi-Fujimoto disease (KFD), or histiocytic necrotizing lymphadenitis, is a subacute inflammatory disorder most often seen in young women with clinicopathologic features suggestive of an infectious etiology. The most commonly suspected infectious agents in KFD are the human herpesviruses EBV, HHV6, HHV7 and HHV8. In order to identify herpesviruses in KFD, we have compared the frequency of detection of herpesvirus DNA with a recently developed real time PCR method, EBER in situ hybridization, and EBV latent membrane protein (LMP) immunostaining in 30 cases of KFD and 12 cases of reactive lymphoid hyperplasia (RLH). EBV DNA was commonly detected, while HSV2, CMV, HHV6, and HHV7 DNA were seldomly detected, and HSV1, VZV, and HHV8 DNA were not detected in KFD. EBV was also commonly detected in RLH. EBER-positive cells with apoptotic features were identified in necrotizing regions of many KFD cases, and LMP-positive cell debris was detected in one case. Viable EBER-positive cells were identified in four of twelve RLH cases, and rare LMP positivity detected in three cases. These data lend support to the notion that the necrotizing lesions in KFD may in some cases be due to a vigorous immune response to EBV-infected lymphoid cells.

Correlating genetic aberrations with World Health Organization-defined histology and stage across the spectrum of thymomas.

Thymomas are thymic epithelial tumors. Because most of them are rich in nonneoplastic T-cells, recurrent genetic aberrations have been reported only in the rare, lymphocyte-poor WHO types A, B3, and C. We have now investigated virtually the whole spectrum of thymomas, including the commoner types AB and B2, microdissecting or culturing neoplastic cells from these lymphocyte-rich thymomas and applying 41 microsatellite markers covering 17 loci on 10 chromosomes. In 28 cases, comparative genomic hybridization data were available. Apart from type A, there was striking heterogeneity between thymomas. Allelic imbalances were seen in 87.3% of the 55 cases, and MSI in 9.9%. Losses of heterozygosity (LOHs) were much the commonest aberration. Overall, they were most prevalent at four regions on chromosome 6. Aberrations elsewhere, affecting mainly 8p11.21 and 7p15.3, suggested a cortical footprint because they recurred only in the thymopoietically active type AB and B thymomas. LOHs were also seen at the adenomatous polyposis coli (APC) locus (5q21-22) in subsets of these thymomas, whereas combined LOHs at the APC, retinoblastoma (13q14.3), and p53 (17p13.1) loci were confined to a subset of B3 thymomas that had possibly evolved from APC-hemizygous B2 thymomas by tumor progression; indeed, thymomas combing B2 plus B3 features are common. Notably, some AB and B thymomas shared LOHs despite their nonoverlapping morphology and different clinical behavior. Finally, allelic imbalances at 8p11.21 and 16q22.1 (CDH1) were significantly more frequent in stage IV metastatic thymomas. We conclude that the WHO-defined histological thymoma types generally segregate with characteristic genetic features, type A thymomas being the most homogeneous. Many findings support the view that B2 and B3 thymomas form a continuum, with evidence of tumor progression. However, other findings imply that types A and AB are biologically distinct from the others, any potential invasiveness being severely restricted by a medullary commitment in the precursor cell undergoing neoplastic transformation.

ST1571 (imatinib mesylate) reduces bone marrow cellularity and normalizes morphologic features irrespective of cytogenetic response.

The tyrosine kinase inhibitor STI571 (imatinib mesylate, Gleevec) is an effective treatment for chronic myeloid leukemia (CML). We examined bone marrow samples from 53 patients with CML who were receiving STI571 in 3 multicenter phase 2 trials to assess morphologic changes and cytogenetic response to this drug. In most patients with initially increased blasts, the bone marrow blast count rapidly decreased during STI571 therapy. Reductions in cellularity, the myeloid/erythroid ratio (commonly with relative erythroid hyperplasia), and reticulin fibrosis (if present pretreatment) also were seen in most patients, resulting in an appearance resembling normal marrow in many cases. Eighteen patients (34%) had some degree of cytogenetic response. Surprisingly, these striking morphologic changes occurred irrespective of any cytogenetic response to STI571. Thus, STI571 seems to affect the differentiation of CML cells in vivo, causing even extensively Philadelphia chromosome-positive hematopoiesis to exhibitfeatures resembling normal hematopoiesis.