VEGF receptors on chronic lymphocytic leukemia (CLL) B cells interact with STAT 1 and 3: implication for apoptosis resistance.

We have previously shown that chronic lymphocytic leukemia (CLL) B cells secrete vascular endothelial growth factor (VEGF) in vitro, have constitutively active VEGF receptors R1 and R2, and respond to exogenous VEGF by specifically upregulating Mcl-1 and XIAP in association with decreased cell death. We found that epigallocatechin (EGCG) decreases VEGF receptor phosphorylation and induces apoptosis in CLL B cells. The mechanism(s) by which VEGF receptor activation increases Mcl-1 and XIAP and promotes survival remains unknown. To further define the signaling pathway mediating VEGF induction of antiapoptotic proteins in CLL B-cells, we investigated downstream effects of VEGF-VEGF receptor binding on the STAT signaling pathway. We find that CLL B cells abundantly express cytoplasmic serine phosphorylated (p)-STAT-1 and p-STAT-3, VEGF-R1/2 are physically associated with p-STAT-1 and p-STAT-3, and p-STAT-3 (but not p-STAT-1) is found in the CLL nucleus. VEGF receptor ligation selectively induces activation and perinuclear translocation of STAT 3 through receptor-mediated endocytosis. The inhibition of VEGF receptor activation with either tyrosine kinase inhibitors or VEGF neutralizing antibodies inhibit VEGF receptor phosphorylation, decrease p-STAT-3 (serine 727), Mcl-1, and induces cell death in CLL B cells. Thus, a VEGF-VEGF receptor pathway in CLL B cells can be linked to activation of STAT proteins that are able to enhance their apoptotic resistance.

B-CLL cells are capable of synthesis and secretion of both pro- and anti-angiogenic molecules.

Initial work has shown that clonal B cells from B-chronic lymphocytic leukemia (B-CLL) are able to synthesize pro-angiogenic molecules. In this study, our goal was to study the spectrum of angiogenic factors and receptors expressed in the CLL B cell. We used ELISA assays to determine the levels of basic fibroblast growth factors (bFGF), vascular endothelial growth factor (VEGF), endostatin, interferon-alpha (IFN-alpha) and thrombospondin-1 (TSP-1) secreted into culture medium by purified CLL B cells. These data demonstrated that CLL B cells spontaneously secrete a variety of pro- and anti-angiogenic factors, including bFGF (23.9 pg/ml +/- 7.9; mean +/- s.e.m.), VEGF (12.5 pg/ml +/- 2.3) and TSP-1 (1.9 ng/ml +/- 0.3). Out of these three factors, CLL B cells consistently secreted bFGF and TSP-1, while VEGF was expressed in approximately two-thirds of CLL patients. Of interest, hypoxic conditions dramatically upregulated VEGF expression at both the mRNA and protein levels. We also employed ribonuclease protection assays to assay CLL B cell expression of a variety of other angiogenesis-related molecules. These analyses revealed that CLL B cells consistently express mRNA for VEGF receptor 1 (VEGFR1), thrombin receptor, endoglin, and angiopoietin. Further analysis of VEGFR expression by RT-PCR revealed that CLL B cells expressed both VEGFR1 mRNA and VEGFR2 mRNA. In summary, these data collectively indicate that CLL B cells express both pro- and anti-angiogenic molecules and several vascular factor receptors. Because of the co-expression of angiogenic molecules and receptors for some of these molecules, these data suggest that the biology of the leukemic cells may also be directly impacted by angiogenic factors as a result of autocrine pathways of stimulation.

Analysis of clonal B-cell CD38 and immunoglobulin variable region sequence status in relation to clinical outcome for B-chronic lymphocytic leukaemia.

Recent reports suggest that the expression of germline (GL) Ig variable region heavy-chain genes (VH) is a negative prognostic factor for B-cell chronic lymphocytic leukaemia (B-CLL) patients and that CLL B-cell CD38 expression may be a surrogate marker of Ig VH gene status. Currently, however, the usefulness of this surrogate marker is controversial. Therefore, our goal was to study the ability of CD38 to act as a surrogate marker for Ig VH somatic mutation (SM), and to identify differences in overall survival (OS), progression-free survival (PFS) and response in B-CLL patients based on these two markers. We first assessed the relationship between CD38 expression and Ig VH status on 131 B-CLL patients, including 66 patients enrolled in three North Central Cancer Treatment Group Trials. Although the mean percentages of CD38+ clonal B cells were significantly higher for patients classified as GL versus SM, CD38 was not a reliable marker for clonal B-cell SM. Overall, GL patients exhibited significantly shorter OS and PFS times than SM patients. Despite the inability of clonal B-cell CD38 expression to predict Ig VH mutation status, patients with < or =30% CD38+ cells did have shorter PFS and OS times than did CLL patients with < 30% CD38+ cells. Thus, the relationship between CD38 expression and Ig VH mutation status in B-CLL is not straightforward. Nevertheless, analysis in a co-operative group clinical trial setting suggests that both B-cell markers alone or in combination may have clinical usefulness. These data strongly encourage the study of these biological markers as they relate to disease heterogeneity in B-CLL.

Human T-cell function in experimental ascorbic acid deficiency and spontaneous scurvy.

Studies in animal models suggest that ascorbic deficiency impairs T-cell-mediated immunity. We studied five normal volunteers hospitalized on a metabolic unit and consuming a strictly controlled diet deficient in ascorbic acid I) after a 5-wk control period of ascorbic acid supplementation (75 mg/day) and 2) after a 9-wk period of no supplementation. Three of the subjects were restudied after a 5-wk period of ascorbic acid supplementation after the deficient period. At the end of both control periods ascorbic acid levels in plasma ranged from 0.9 to 1.3 mg/dl and in leukocytes from 19 to 30 microgram/10(8) cells. At the end of the deficient period levels of ascorbic acid in plasma ranged from 0.09 to 0.15 mg/dl and in leukocytes from 6.2 to 10 microgram/10(8) cells, levels at or below those frequently found in frank scurvy. None of the T-cell parameters tested including mitogen responsiveness to phytohemagglutinin and percentage of T-cells bearing receptors for IgM (helper cells) and IgG (suppressor cells) was different in the deficient period compared to the control periods. One patient with spontaneous scurvy (plasma ascorbic acid 0.07 mg/dl, leukocytic ascorbic acid 4.9 microgram/10(8) cells) was studied at the time of admission and after vigorous ascorbic acid repletion. All T-cell parameters after repletion were unchanged from admission. We conclude that in man ascorbic acid deficiency, even at the scorbutic level, does not alter T-cell numbers or impair in vitro T-cell function.