Long-term follow-up of patients immunized with AN1792: reduced functional decline in antibody responders.

BACKGROUND: Immunization of patients with Alzheimer's disease (AD) with synthetic amyloid-beta peptide (Abeta(42)) (AN1792) was previously studied in a randomized, double-blind, placebo-controlled phase 2a clinical trial, Study AN1792(QS-21)-201. Treatment was discontinued following reports of encephalitis. One year follow-up revealed that AN1792 antibody responders showed improvements in cognitive measures as assessed by the neuropsychological test battery (NTB) and a decrease in brain volume compared with placebo. METHODS: A follow-up study, Study AN1792(QS-21)-251, was conducted to assess the long-term functional, psychometric, neuroimaging, and safety outcomes of patients from the phase 2a study 4.6 years after immunization with AN1792. The results were analyzed by comparing patients originally identified as antibody responders in the AN1792 phase 2a study with placebo-treated patients. RESULTS: One hundred and fifty-nine patients/caregivers (30 placebo; 129 AN1792) participated in this follow-up study. Of the 129 AN1792-treated patients, 25 were classified in the phase 2a study as antibody responders (anti-AN1792 titers > or = 1:2,200 at any time after the first injection). Low but detectable, sustained anti-AN1792 titers were found in 17 of 19 samples obtained from patients classified as antibody responders in the phase 2a study. No detectable anti-AN1792 antibodies were found in patients not classified as antibody responders in the phase 2a study. Significantly less decline was observed on the Disability Assessment for Dementia scale among antibody responders than placebo-treated patients (p=0.015) after 4.6 years. Significant differences in favor of responders were also observed on the Dependence Scale (p=0.033). Of the small number of patients who underwent a follow-up MRI, antibody responders showed similar brain volume loss during the follow-up period subsequent to the AN1792 phase 2a study compared with placebo-treated patients. CONCLUSIONS: Approximately 4.6 years after immunization with AN1792, patients defined as responders in the phase 2a study maintained low but detectable, sustained anti-AN1792 antibody titers and demonstrated significantly reduced functional decline compared with placebo-treated patients. Brain volume loss in antibody responders was not significantly different from placebo-treated patients approximately 3.6 years from the end of the original study. No further cases of encephalitis were noted. These data support the hypothesis that Abeta immunotherapy may have long-term functional benefits.

A fourth case of 8p11 myeloproliferative disorder transforming to B-lineage acute lymphoblastic leukaemia. A case report.

A 56-year-old male presented with inguinal lymphadenopathy and leucocytosis (WBC 98 x 10(9)/l). Bone marrow morphology showed myeloid hyperplasia, with eosinophilia. Cytogenetic analysis showed no evidence of the Philadelphia chromosome, and fluorescence in situ hybridisation studies for the BCR/ABL fusion were negative. All cells examined showed the t(8;13)(p11;q12) translocation. Six weeks after presentation, the disease progressed to an acute lymphoblastic leukaemia (ALL). The lymphoblasts were CD19/CD10 dual positive. Cytogenetic analysis again showed the t(8;13) translocation, with no additional abnormalities. There have been at least 14 reported cases of the t(8;13) myeloproliferative disorder to date, of which only 3 transformed to B-lineage ALL: our case is the 4th.

Characterization of cryptic rearrangements and variant translocations in acute promyelocytic leukemia.

Acute promyelocytic leukemia (APL) is typified by the reciprocal translocation, t(15; 17)(q22; q21), leading to the formation of PML-RARalpha and RARalpha-PML fusion genes. We have characterized 7 cases of morphologic APL found to lack the t(15; 17) on conventional cytogenetic assessment. In 6 of 7 cases, cryptic PML-RARalpha rearrangements were identified by reverse transcriptase-polymerase chain reaction and fluorescent in situ hybridization (FISH); whereas, in the remaining patient, APL was associated with the variant translocation, t(11; 17)(q23; q12-21), leading to the formation of PLZF-RARalpha and RARalpha-PLZF fusion genes. In each of the cases with cryptic PML-RARalpha rearrangements, PML-RARalpha transcripts were detected in the absence of RARalpha-PML, consistent with the concept that PML-RARalpha is the critical oncogenic fusion protein. In 4 of these cases with evaluable metaphase spreads, the occurrence of a nonreciprocal translocation was confirmed by FISH with sole formation of the PML-RARalpha fusion gene; in 3 cases with morphologically normal chromosomes 15 and 17, RARalpha was inserted into PML on 15q, whereas in the remaining patient the PML-RARalpha fusion arose due to insertion of 15q-derived material including PML into RARalpha on 17q. Immunofluorescence studies were performed using antibodies raised against PML and PIC 1, a ubiquitin-homology domain protein previously identified as an interaction partner of PML. In acute myeloid leukemia (AML) of subtypes other than M3, PIC 1 was localized to the nuclear membrane and colocalized with PML within discrete nuclear bodies. In APL cases with cryptic PML-RARalpha rearrangements, the characteristic microparticulate pattern of PML staining was detected with partial colocalization with PIC 1, indicative of disruption of the nuclear bodies; whereas in t(11; 17)-associated APL, PML and PIC 1 remained colocalized within discrete nuclear bodies, as observed in non-APL cases. Although deregulation of the putative growth suppressor PML and delocalization of other nuclear body constituents have been advocated to play a key role in the development of t(15; 17)-associated APL, the present study shows that disruption of PML nuclear bodies per se is not a prerequisite for the pathogenesis of APL.

Rapid production of diversity during the progression of a mixed lineage leukaemia.

A leukaemia presenting with two morphologically different blast populations failed to respond to either antimyeloid or antilymphoid treatment and showed a rapid clinical progression. Immunophenotyping provided good evidence for two blast populations, one lymphoid and the other lymphoid with granulocyte monocytic markers. Two different gene rearrangements within JH were also observed with band densities corresponding to the sizes of the two blast cell populations. A t(19; 22) translocation was observed in almost all cells at presentation one of which evolved into a subclone, becoming dominant in the terminal phase of the disease. We show here both the clonal evolution and clonal competition that occurred in this leukaemia and suggest that the potential of the tumour stem line for rapidly producing diversity was the reason for the resistance to treatment.

A t(8;14)(q24;q32) in a T-lymphoma/leukemia of CD8+ large granular lymphocytes.

Chromosome studies in a case of T cell lymphoma/leukemia, in which a high proportion of the dividing cells had a t(8;14)(q24;q32) similar to that seen in Burkitt's lymphoma, are described. The tumor cells had a mature T cell phenotype (TdT-,CD3+,CD8+,CD4-) and were morphologically large granular lymphocytes and immunoblasts, both cell types with similar lysosomal granules in the cytoplasm. The immunoglobulin heavy chain gene and the T cell receptor beta chain gene were not rearranged, while the T cell receptor gamma chain gene was polyclonally rearranged. Mitoses were obtained only from spontaneously dividing cells in the absence of mitogens; 49 of the 50 metaphases analyzed were chromosomally abnormal and had a t(1;22)(q12;q13) and dup(1)(q31q32) in all of them; 48 metaphases had in addition a t(8;14)(q24;q32) which presumably arose during clonal evolution. The latter may be associated with the aggressive behavior of this T cell disorder by comparison with other proliferations of large granular lymphocytes. Although abnormalities involving 14q32 are characteristic of B cell disorders, they have also been described in T cell malignancies, suggesting that genes transcribed in T cells and/or oncogenic sequences significant in T cell neoplasia are present in 14q32.

Cytogenetic studies on prolymphocytic leukemia. II. T cell prolymphocytic leukemia.

We report chromosome abnormalities in 15 cases of T cell prolymphocytic leukemia (T-PLL). All cases were characterized by clinical, morphological, and membrane marker analysis. The most frequent abnormality was an inv(14)(q11q32) observed in nine cases. The T cell receptor (TCR) alpha chain gene is localized to 14q11 and the immunoglobulin heavy-chain gene to region 14q32. Four cases also had translocations involving 14q11. Trisomy or multisomy for 8q resulting from an i(8q) or from rearrangements with 8p12 as the breakpoint was observed in nine cases, and a deletion of 6q was found in four cases. Trisomy or partial trisomy for 7q was observed in four cases, of which two had abnormalities of band 7q35 to which the TCR beta chain gene is mapped. The expression of Tac antigen, investigated in 27 cases of human T cell leukemia virus I-negative chronic T cell leukemia, which included the 15 cases of T-PLL, showed a good correlation with abnormalities of 7q35. Our studies on chronic T leukemias suggest that inv(14)(q11q32) and trisomy for 8q are abnormalities characteristic of T-PLL.

Cytogenetic studies on prolymphocytic leukemia. 1. B-cell prolymphocytic leukemia.

We describe clonal chromosome abnormalities in 13 new cases of B-cell type prolymphocytic leukemia (B-PLL) investigated using pokeweed, lipopolysaccharide B, TPA (phorbol ester), and Epstein-Barr virus (EBV) as mitogens. B-PLL showed a much better response to all four mitogens when compared with B-cell chronic lymphocytic leukemia (B-CLL). A 14q+ was the most frequent abnormality and was observed in 7 of the 13 cases. A t(11;14)(q13;q32) was observed in 2 patients in this series and in 2 cases from a previous series of 9 patients studied in this laboratory, giving an incidence in B-PLL of 18% for this abnormality. The more frequent rearrangement of both IgH genes in B-PLL when compared to B-CLL may predispose to a higher incidence of 14q+ in B-PLL. Trisomy 12 which is a feature of B-CLL was observed in one case in the present series. Other abnormalities of chromosome 12 included 12p-(p12-13) in 2 cases and t(12;14)(q22;q32) in 1 case. The t(6;12) previously described as a specific abnormality in B-PLL was not observed in the 22 cases (13 present series, 9 previous series) studied in our laboratory.