Abstract
Background
The Notch signaling pathway is crucial in T-cell development, Notch1 mutations are frequently present in T-cell acute lymphoblastic leukemia (T-ALL). To investigate the feature of Notch1 mutation and its corresponding expression level in Chinese patients with T-ALL, detection of mutation and the expression level of Notch1 gene was preformed using RT-PCR, sequencing and real-time PCR respectively.
Results
Two Notch1 point mutations (V1578E and L1593P) located on HD-N domain were identified in three cases out of 13 T-ALL patients. The mutation on 4733 position (V1578E) found in two cases was a novel mutation. The overexpression of Notch1 was detected in all samples with T-ALL, moreover, significantly higher expression of Notch1 was detected in the T-ALL with Notch1 mutation group compared with T-ALL with WT Notch1 group (p = 0.0192).
Conclusions
Higher expression of Notch1 was associated with Notch1 mutation, more novel mutation of this gene might be identified in different populations and its contribution to the molecular pathogenesis of T-ALL is needed further research.
Background
T-cell acute lymphoblastic leukemia (T-ALL) which occurs mainly via the proliferation of malignant T cell clones, accounts for 15% of newly diagnosed ALL cases in children and 20-25% of ALL cases in adults [1]. Overall, these are aggressive malignancies that do not respond well to chemotherapy and have a poorer prognosis than their B-cell counterparts [2]. Complex acquired genetic aberrations include chromosomal translocations (frequently involving TCR), as well as gene rearrangements and mutations resulting in abnormal expression of oncogenes like Notch1 may be associated with the advance and resistance to treatment of this disease [3].
Notch1 was discovered in 1991 through analysis of rare T-cell lymphoblastic leukemia/lymphoma with balanced (7;9) translocation [4]. Acquired Notch1 mutations are present in about 50% of T-ALL [5,6]. More than hundred different mutations frequently involved in heterodimerization domain (HD), transactivation domain (TAD) and praline, glutamic acid, serine, threonine-rich (PEST) domains of Notch1 were reported in patients with T-ALL from a lot of researcher groups in different countries [5-10]. Little is known the incidence and feature of Notch1 mutations in Chinese T-ALL patients [10], in this study, we detected the Notch1 mutations in 13 Chinese patients with T-ALL and analyzed the corresponding expression level of Notch1 gene.
Materials and methods
Samples
Thirteen newly diagnosed and untreated cases of T-ALL, 11 males and 2 females (6-55 years old; median age: 23.5 years) were included in this study, along with 20 healthy individuals as controls. The samples were collected with informed consent. All procedures were conducted in accordance with the guidelines of the medical ethics committees of the Health Bureau of Guangdong Province, China. The peripheral blood mononuclear cells (PBMCs), RNA extraction using Trizol reagent (Trizol®, Invitrogen, Carlsbad, CA, USA) and cDNA synthesis using random hexamer primers and reverse transcriptase (SuperScript® III, Invitrogen, Carlsbad, CA, USA) were performed according to the manufacturer's instructions.
RT-PCR and sequencing
To amplify different domain and exon of Notch1 according the structure of the Notch1 gene, 4-pair primers were purchased, which covered different exons, where the mutations happen frequently (Table 1) [5,6]. RT-PCR was performed as our previous study, positive control (Jurkat cell line) and negative control (non-template) were included in each reaction [11,12]. The PCR products were directly sequenced using a BigDye Terminator v3.1 Cycle Sequencing kit (Perkin Elmer, ABI) and the ABI PRISM 3100-Avant genetic analyzer. The sequences from different samples of T-ALL were analyzed with the BLAST software (http://blast.ncbi.nlm.nih.gov/Blast.cgi) to identify the mutations of Notch1 gene.
Table 1.
List of the primers used in RT-PCR and real-time PCR for Notch1 gene amplification
| Primer 5,6 | Sequence | Domain | PCR | Function |
|---|---|---|---|---|
| notch26 + 27-F | 5'-ACGACCAGTACTGCAAGGACC - 3' | HD/exon 26 + 27 | RT-PCR | Sense |
| notch26 + 27-R | 5'- AAGAACAGAAGCACAAAGGCG - 3' | Antisense | ||
| notch28-F | 5'- TCGCTGGGCAGCCTCAACATCC - 3' | HD/exon28 | RT-PCR | Sense |
| notch28-R | 5'- ACTCATTCTGGTTGTCGTCC - 3' | Antisense | ||
| Notch TAD-F | 5'- GCCCTCCCCGTTCCAGCAGTCT - 3' | TAD | RT-PCR | Sense |
| Notch TAD-R | 5'- GCCTGGCTCGGCTCTCCACTCA - 3' | Antisense | ||
| Notch PEST-F | 5'- CAGATGCAGCAGCAGAACCTG - 3' | PEST/exon34 | RT-PCR | Sense |
| Notch PEST-R | 5'- AAAGGAAGCCGGGGTCTCGT - 3' | Antisense | ||
| Notch1-f | 5'-GCGACAACGCCTACCTCT-3' | real-time PCR | Sense | |
| Notch1-r | 5'-CTGCTGGCACAGTCATCC-3' | Antisense | ||
| β2M-f | 5'-TACACTGAATTCACCCCCAC-3' | real-time PCR | Sense | |
| β2M-r | 5'-CATCCAATCCAAATGCGGCA-3' | Antisense | ||
Note: HD heterodimerization domain; TAD transactivation domain; PEST PEST domain.
Real-time quantitative RT-PCR (qRT-PCR)
Expression levels of Notch1 and the reference gene β2M were determined by SYBR Green I real-time PCR. PCR was performed as our previous description [12,13]. The 2(-ΔΔT) method was used to present the data of the genes of interest relative to an internal control gene [12-14]. The sequences of primers used in qRT-PCR were listed in Table 1.
Statistical analysis
Univariate analyses were done using the Mann-Whitney test to compare manes of Notch1 expression level between T-ALL with Notch1 mutations or with wild-type (WT) Notch1 status. P < 0.05 was considered as statistically significant.
Results
Notch1 mutation and polymorphirsm in T-ALL
Notch1 expression was detected in all of 13 cases with T-ALL by RT-PCR (Figure 1). The search for Notch1 mutation was performed in exon 26, 27 and 28 (HD), TAD and PEST domain. The PCR products were direct sequenced and revealed two mutations at nucleotide position 4733 and 4778 respectively. The mutation on 4733 position was identified in two different cases, the nucleotide sequence was changed from GTG to GAG (codon 1578), thereby leading to an amino acid exchange (Valine to Glutamic), this was a novel mutation. While the mutation on 4778 position was identified in one case, the nucleotide sequence was changed from CTG to CCG (codon 1593), leading to an amino acid exchange from Leucine to Proline. All of mutations presented were heterozygous genetic alteration. And the mutations were located on HD N-terminus (Figure 2). Sequence analysis of Notch1 segments revealed further a nucleotide exchange in all samples analyzed at position 5094, where we found a cytosine instead of a thymine, the alteration affected the third position of the codon 1698 and did not alter the amino acid sequence (data not shown).
Figure 1.
Results of RT-PCR amplification for Notch1 gene using different primer pairs which located in different domains. 1: 100 bp DNA ladder, 2-3: Amplicon of Exon 26 and 27 (652 bp), 4-5: Amplicon of Exon 28 (316 bp), 6-7: Amplicon of TAD domain (666 bp), 8-9: Ampilcon of PEST domain (530 bp).
Figure 2.
Notch1 mutations in 3 cases with T-ALL (Mut sample) compared with a normal sequence of Notch1 (WT sample). Heterozygous mutations were identified in position 4733 (codon 1578) and 4778 (codon 1593) in Notch1 gene.
Expression level of Notch1 in T-ALL
In order to compare the expression level of Notch1 gene in different T-ALL samples with Notch1 mutations or with wild-type (WT) Notch1 status, the expression level of Notch1 gene was analyzed by real-time PCR, in comparison with healthy controls (0.37 ± 0.33), significantly higher expression of Notch1 was found in both T-ALL with WT Notch1 (6.34 ± 7.03) (p = 0.0006) or with Notch1 mutations (Mut Notch1) (20.47 ± 10.81) (p < 0.0001) (Figure 3). Moreover, significantly higher expression of Notch1 was detected in the T-ALL with Mut Notch1 group compared with WT Notch1 group (p = 0.0192) (Figure 3). Interesting, the expression level of Notch1 in two cases with WT Notch1 T-ALL (24.28 and 9.06 respectively), which were not identified any mutation in the present study, was as high as the samples with Notch1 mutation.
Figure 3.
The expression levels of Notch1 gene in T-ALL with Notch1 mutation (Mut T-ALL), T-ALL with wild type Notch1 (WT T-ALL) and healthy individuals (HI) groups.
Discussion
Notch1 signaling is crucial for T-cell differentiation and proliferation, mutational activation of Notch1 is an important factor in T-ALL pathogenesis [5,7]. Translocation and mutations of Notch1 may alter its function resulting in overexpression and independent activation [15]. In this study, Notch1 mutations were identified in 3 Chinese patients with T-ALL, the incidence of Notch1 mutation was only 23.08% (3/13), it seemed relatively low in comparison with previous studies from different European and American countries [5,6,16]. There are rare studies described the incidence of Notch 1 mutation in Chinese cases, one report by Zhu et al showed that Notch1 mutation was found in 29 patient out of 77 cases (37.7%) with Chinese T-ALL [10]. Similar incidence (22%) of Notch 1 mutations was reported by a research group from Turkey [8]. However, further research is needed to collect and investigate more samples and find out the representational results.
The higher frequency of Notch1 mutation is found in HD, TAD and PEST domains [5-10]. In the present study, we used the 4 pair primers covered all the HD, TAD and PEST domains to amplify and sequence. Two mutations were identified in three cases, one was the mutation on 4778 position (L1593P) which was reported in previous studies [10,17], while the another mutation was identified on 4733 position (V1578E) in two different cases with T-ALL, to our best knowledge, this is a novel identified mutation. The effect of the novel mutation is needed to evaluate by further functional analysis. Both mutations were located at HD N-terminus (HD-N) domain. The Notch1 HD-N mutation may destabilize the subunit interaction and do not require the ligand-binding domain to activate signaling, resulting in constitutive Notch1 activation and subsequent cell transformation [9,17]. Based on the results, we compared the expression level of Notch1 in T-ALL with WT Notch1 or with Mut Notch1 group, definitive result indicated that the expression level of Notch1 was significant associated with Notch1 mutation in HD-N domain, significantly higher expression of Notch1 was detected in the T-ALL with Mut Notch1 group compared with WT Notch1 T-ALL group. However, overexpression of Notch1 was a common feature in all T-ALL patients, whether the mechanism of Notch1 overexpression in mutation or WT samples is different, it remains an open question. Although no mutation was detected in HD, TAD or PEST domains, high expression level of Notch1 in two cases with T-ALL in the present study was thought that might has potential mutation in the other domains, whole notch1 gene sequence analysis for these cases is needed to follow up.
In the present study, we were unable to identify mutation of Notch1 in PEST domain which regulates protein turnover by targeting proteins to the ubiquitin-proteosome complex for subsequent degradation [9,15]. However, a high incidence (4/15 cases) of Notch1 mutation in PEST domain was reported in Indian T-ALL patients [9], while lower incidence was described from a study in Chinese T-ALL patients (5/77, 6.5%) [15], as well as in Turkish patients (7%) and German patients (8.2%) [7,18], the difference may due to the racial diversify.
In summary, Notch1 mutations including a novel mutation were identified in a small cohort of Chinese T-ALL cases, and concomitant significantly higher expression level of Notch1 was found. More ongoing study was performed to follow up its predictive value and to elucidate its contribution to the molecular pathogenesis of T-ALL.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
YQL contributed to concept development and study design. CLL and SHC performed PCR and sequencing, HTZ, LJY and YBZ performed the real-time PCR. CYW, LJY, BL and HT were responsible for collection of clinical data. YQL and CLL and HTZ coordinated the study and helped drafting the manuscript. All authors read and approved the final manuscript.
Contributor Information
Chunlan Lin, Email: linchunlan@126.com.
Haitao Zheng, Email: avery-2006@163.com.
Chunyan Wang, Email: wcy163@163.com.
Lijian Yang, Email: jnyanglijian@163.com.
Shaohua Chen, Email: jnshaohuachen@163.com.
Bo Li, Email: libo517@hotmail.com.
Yubing Zhou, Email: zhouyubing@126.com.
Huo Tan, Email: tanhuo.2008@163.com.
Yangqiu Li, Email: yangqiuli@hotmail.com.
Acknowledgements
This work was supported by Grants from National Natural Science Foundation of China (no. 30871091), the Fundamental Research Funds for the Central Universities (No. 21610603) and Science and Technology Innovation Key Project of Guangdong Higher Education Institutes (kjcxzd1013).
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