VEGF and bFGF gene polymorphisms in Polish patients with B-CLL

Among a variety of angiogenic factors involved in the B cell chronic lymphocytic leukemia (B-CLL), vascular endothelial growth factor (VEGF) and basic fibroblast growth factor (bFGF) were identified. Their levels have been regarded as prognostic markers of the progression of disease. The objective of the present study was to assess whether polymorphisms located within the genes coding for these key angiogenic activators contribute to disease susceptibility and/or progression in patients with B-CLL. For this purpose, 180 individuals were investigated, including 68 B-CLL patients and 112 healthy controls. All individuals were typed for the VEGF (936 C > T) and bFGF (−921 C > G) alleles using PCR–RFLP technique. Only a slight prevalence of the VEGF T variant was observed among patients as compared to healthy individuals (p = 0.095) with a significant difference when high risk (stage III/IV) patients were considered (OR = 3.81, p = 0.045). No other significant association was observed between the VEGF polymorphism and progression of the disease. The VEGF alleles and genotypes segregated similarly in patients with different stage of the disease according to Rai classification. No significant relationships were also observed for the bFGF polymorphism with either susceptibility to B-CLL (when compared to control group) or progression of the disease. These results suggest the possible association of the VEGF polymorphism with high risk B-CLL.


Introduction
Dysregulation of angiogenesis occurs in various pathologies and is one of the hallmarks for cancer. The importance of this biological process in normal hematopoietic cell development and the pathophysiology of several malignancies, including B cell chronic lymphocytic leukemia (B-CLL), has been recently reported [1][2][3]. Patients with CLL have been demonstrated to have detectable levels of both plasma and cellular pro-and anti-angiogenic cytokines, as well as abnormal neovascularization in the marrow and lymph nodes [4][5][6]. Recent evidence suggests that vascular endothelial growth factor (VEGF)-based autocrine pathway promotes the survival of CLL B cells in part through upregulation of anti-apoptotic proteins [7]. Moreover, interactions between CLL B cells and their microenvironment generate alterations in the secretion of angiogenic factors that result in enhanced leukemic B cell resistance to apoptotic cell death [8]. Among a variety of angiogenic factors involved in the CLL, vascular endothelial growth factor and basic fibroblast growth factor (bFGF) were identified [9]. Their levels have been regarded as prognostic markers of the progression of the disease [10][11][12][13][14] in patients with B-CLL, including those of Polish origin. The data on the role of the VEGF and bFGF in CLL are summarized in Table 1.
The objective of the present study was to assess whether polymorphisms located within the genes coding for these key angiogenic activators (VEGF and bFGF), contribute to disease susceptibility and/or progression in patients with B-CLL.

Patients and controls
Sixty-eight patients (F/M = 27/41), aged 39-85 (median 69) years, with B-CLL were investigated. B-CLL was diagnosed according to defined clinical, morphological and immunological criteria. All patients gave their informed consent prior to their inclusion in the study. The study has been approved by the appropriate ethics committee.
Patients were treated at the Department of Hematology, Wroclaw Medical University. According to the modified Rai classification [15], there were 17, 28 and 12 patients in stage 0, I and II of the disease, respectively. The other 11 patients presented with more advanced disease: 6 and 5 with stage III and IV, respectively. In addition, 112 healthy individuals of both sexes (F/M = 57/55) served as a control group.
VEGF and bFGF genotyping DNA was isolated from the whole blood taken on EDTA with the use of Qiagen DNA Isolation Kit (Qiagen GmbH, Hilden, Germany).
The VEGF and bFGF alleles were detected using a polymerase chain reaction restriction fragment length polymorphism (PCR-RFLP) assay.
In brief, DNA was extracted from peripheral blood taken on EDTA using silica membranes (QiAmp Blood Kit, Qiagen, Hilden, Germany) following the recommendations of the manufacturer. A 208-bp-long fragment of the 3 0 untranslated region (UTR) of the VEGF gene was amplified using the following primers: forward, 5 0 -GAG TGT CCC VEGF mRNA and protein are produced in CLL cells [4] VEGF is expressed on B-CLL granulocytes and lymphocytes; VEGF receptors, VEGFR-1 and VEGFR-2, are expressed on B-CLL cells [6] VEGF levels do not differ between plasma of CLL patients and healthy controls [5] Bone marrow stromal cells (BMSC) treated with CLL microvesicles produce VEGF on a higher level than untreated healthy BMSC, but not as high as CLL-BMSC; [3] VEGF 165 is the main and overexpressed isoform in CLL-BMSC compared to healthy cells; VEGF 121 is poorly expressed, and isoforms VEGF 189 and VEGF 206 are not detected VEGF serum level is higher in CLL patients than in healthy individuals; [13] VEGF and VEGFR-2 levels are significantly higher in serum of patients in III or IV than in those in 0-II Rai stage of the disease; VEGF and VEGFR-2 serum levels correlate in CLL patients VEGF supports antiapoptotic and cytoproliferative effect of CD154 in CLL cells; [7] Inhibition of VEGF and its receptor decreases CLL cells survival VEGF produced by bone marrow stromal cells, but not by CLL cells, decreases CLL cells apoptosis [8] Increased expression of VEGF receptors correlates with clinical stage [24] High serum levels of VEGF correlate with increased risk of disease progression in early B-CLL [11] Low level of VEGF correlates with worse outcome in B-CLL patients with low level of b2-microglobulin (good prognosis indicator) what may lead to decreased survival of patients in 0 to II stadium of the disease [12] Targeting VEGF receptors effectively induces apoptosis in primary CLL cells and reduces tumor growth in a VEGFpositive CLL-like xenograft mouse model [25] bFGF Plasma levels of bFGF in CLL patients are significantly higher compared to levels of other proangiogenic molecules (i.e. VEGF) in plasma of these patients [1] Plasma levels of bFGF are significantly higher in patients with B-CLL compared to healthy controls [5] Serum levels of bFGF are statistically higher in patients with B-CLL than in healthy controls; serum bFGF level was significantly higher in patients with progressive than in those with stable disease [14] bFGF upregulates BCL-2 expression in B-CLL [9] Increased expression of bFGF correlates with clinical stage [10] TGA CAA CAC TGG CA-3 0 , reverse, 5 0 -AGC AGC AGA TAA GGG ACT GGG GA-3 0 as previously described [16].
The following primer pair was used for amplification of a 437-bp-long fragment of the bFGF gene promoter region: 5 0 -TGA GTT ATC CGA TGT CTG AAA TG-3 0 and 5 0 -TAAC were considered statistically significant, and those between 0.05 and 0.1 as indicative of a trend.

Results and discussion
The former studies on the role of the VEGF and bFGF in B-CLL regarded their serum levels or cellular expression as prognostic markers of the progression of the disease [10][11][12][13][14].
As for the Polish patients with CLL, our former study documented the significantly higher bFGF levels in B-CLL patients than in controls [14], while Gora-Tybor et al. [13] described the differences in VEGF serum levels between patients and controls, and patients in Rai stage III and IV versus those in Rai stage 0-II (summarized in Table 1).
As VEGF production appeared to have a significant effect on the susceptibility to CLL and the course of the disease, in our present study, we wanted to determine whether functionally relevant polymorphism within the VEGF encoding gene (pp. 936 C [ T in the 3 0 -UTR) could contribute to the risk of this malignant disease. The previous reports documented significantly lower VEGF plasma levels in carriers of the 936 T allele what could be attributed to the 936 C/T exchange leading to the loss of a potential binding site for transcription factor AP-4 (activating enhancer-binding protein 4) [18].
The bFGF (pp. -921 C [ G) promoter polymorphism was also studied. Polymorphisms within the promoter region of the bFGF gene may interfere with existing transcription factor binding sites or produce new binding sites and therefore influence the bFGF gene expression [17].
In the present study, C to T substitution at position 936 within the 3 0 -UTR of the VEGF gene and C to G substitution at position -921 within the promoter region of the bFGF gene were analyzed in order to determine whether the presence of these allelic variants is associated with susceptibility and progression of the disease in CLL patients.
As mentioned before, unfavorable CLL progression was reported to be associated with high VEGF levels and increased VEGF expression with a lack of the VEGF 936 T variant [18]. That is why the less frequent representation of the VEGF T allele among patients, especially those presented with more advanced disease, was expected. However, only a slight prevalence of the VEGF T variant was observed among patients as compared to healthy individuals (20/68 vs. 20/112, OR = 1.91, p = 0.095, Table 2). This relationship reached statistical significance when a group of high risk patients was considered. Among 11 patients in III or IV stage of the disease, 5 (45 %) were carrying the T allele as compared to 20 out of 112 (18 %) controls (OR = 3.81, p = 0.045, Table 2).
No other significant association was observed between the VEGF polymorphism and progression of the disease. The VEGF alleles and genotypes segregated similarly in patients with different stage of the disease according to Rai classification, beta2 microglobulin serum level and survival.
No other significant relationships were also observed for the bFGF polymorphism with either susceptibility to B-CLL (when compared to control group, Table 2) or progression of the disease.
Thus, no differences in VEGF and/or bFGF alelle and/or genotype distribution were noted between subgroups with stage 0-II versus III-IV according to modified Rai staging as well as males versus females (individual data not shown).
Intensive literature search was performed in order to compare the VEGF and bFGF alleles and genotypes distribution in Caucasian B-CLL patients and controls of other studies with our present results.
To our knowledge, there are no published data on the role of VEGF and bFGF polymorphisms in B-CLL (thus, our report present novel observations not previously described).
There were more studies investigating the distribution of the VEGF alleles showing comparable results. Allele frequencies of the present study are in agreement with those previously published for healthy Caucasians [21][22][23].
These data suggest that while the bFGF (-921 C [ G) polymorphism does not significantly contribute to susceptibility and progression of the disease in Polish patients with B-CLL, the VEGF (936 C [ T) polymorphism may be associated with high risk disease.
Obviously, these results should be regarded as preliminary and confirmed in the more extended study, including patients from the other centers.