Transcript 슬라이드 1
Molecular characterization of the DYX1C1 gene and
its application as a colorectal cancer biomarker
Yun-Ji Kim1*, Jae-Won Huh1,2*, Dae-Soo Kim3, Min-In Bae1, Tae-Oh Kim4, Ja-Rang Lee1, Hong-Seok Ha1, Kung
Ahn1, Yu-Na Noh1, Sang-Je Park1, Jin-Han Bae1, Yi-Deun Jung1 and Heui-Soo Kim1,3§
1 Division
of Biological Sciences, College of Natural Sciences, Pusan National University, Busan 609-735, Republic of Korea
2 National Primate Research Center (NPRC), KRIBB, Ochang, Chungbuk 363-883, Republic of Korea
3 PBBRC, Interdisciplinary Research Program of Bioinformatics, College of Natural Sciences, Pusan National University, Busan 609-735, Republic of Korea
4Division of Gastroenterology Department of Internal Medicine, College of Medicine Pusan National University, Pusan National University Hospital, Busan 602739, Republic of Korea
http://www.primate.or.kr
Abstract
DYX1C1 has three alternatively spliced transcripts. So we expect that alternative transcripts of DYX1C1 are used as a biomarker to
detect specific cancer. RT-PCR analysis is conducted in order to detect expression of the DYX1C1 gene and the PCR products were
analyzed using the Image J program to compare the expression levels of each transcript. We found one of the transcripts was
directly associated with an HERV-H LTR element that could be translated into protein sequence. Four new alternative transcripts
were identified by RT-PCR analysis with various human tissue samples including 5 normal and adjacent tumor tissue sets. Semiquantitative RT-PCR analysis showed the transcriptional activity of V3 and V2 was higher in normal than in tumor tissue
samples, especially in the colorectal tissue samples. Our results indicated that alternatively spliced transcript variants of the
DYX1C1 gene could be used as cancer biomarkers to detect colorectal cancer.
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Introduction
Materials & Methods
Biomarker
The identification of cancer biomarkers has been a major focus of investigation in the
field of cancer research. However, effective and reproducible cancer biomarker
developments are still far off and enormous efforts are needed in this area (Brinkman et
al. 2004). In cancerous cells, splicing mechanisms are significantly altered by defects in
splice sites caused by frequent point mutations (Venables et al. 2004; Skotheim et al.
2007). Aberrant neuronal-specific splicing of amphiphysin 2 in non-neuronal cells may
contribute to the progression human melanoma (Ge et al. 1999). Expression levels of
alternatively spliced variants of survivin are not equal to each other in malignant breast
tissues. In the case of breast cancer, different survivin transcripts show different
functions in the progression of apoptosis (Ryan et al. 2005; Pajares et al. 2007). Our study
focused on the application of cancer biomarkers using transcription variants.
Bioinformatics
( in silico analysis DYX1C1 gene )
PCR and RT – PCR in human tissues
and various normal/tumor sets
Alignment & Image J analysis
Application to colorectal patients
DYX1C1
DNA
DYX1C1 is a recently identified candidate gene for dyslexia. Disruption of the gene by a
translocation was detected in dyslexia patients (Taipale et al. 2003; McGrath et al. 2006).
The DYX1C1 gene maps to chromosome 15q21 and consists of 10 exons dispersed over
about 78 kb of genomic DNA. The protein sequence encoded by DYX1C1 is 420 aa in
length and the protein sequences of the nonhuman primate homolog are 98.6-99.5%
similar to that of humans (Taipale et al. 2003). DYX1C1 is expressed broadly in several
adult tissues including lung, kidney, and brain (Taipale et al. 2003; Wang et al. 2006),
where its protein is localized in white matter including the nuclei of cortical neurons and
glial cells (Taipale et al. 2003; Fisher and Francks 2006). Eight single nucleotide
polymorphisms (SNPs) in the DYXICI genes of 20 patients with reading disabilities were
detected (Taipale et al. 2003; McGrath et al. 2006). The 1249G-to-T and -3G-to-A
mutations were among the SNPs found more frequently in patients with dyslexia than in
controls (Fisher and Francks 2006). Developmental dyslexia is associated with migration
anomalies in the neocortex as well genetic susceptibility (Pennington and Smith 1983;
Galaburda et al. 1985; Smith et al. 1998; Chang et al. 2005; Sokol et al. 2006). DYX1C1
plays a role in the migration of neocortical neurons. Specifically it is required for the
transition of the multipolar stage of migration (Wang et al. 2006).
Human genomic
DNA
Bioinformatics
Sequencin
g analysis
vector
PCR, RT-PCR
Plasmid isolation
Electrophoresis
inoculation
ligation
transformation
Kim et al. Molecular characterization of the DYX1C1 gene and its application as a cancer biomarker.
J Cancer Res Clin Oncol. 2008 in press
Results and Discussion
Fig.1 Spliced variants of the DYX1C1 gene and their structural
analysis
AS1
S1
EXON1
2
3
4
5
6
7
8
Fig.2 Expression patterns of HERV-H LTR-associated (A) and unassociated (B) DYX1C1 transcripts in normal human
tissues. G3PDH indicates the positive control.
Fig.4 Comparative analysis of the other transcripts (V2, V3)
in normal (N) and tumor (T) samples. G3PDH indicates the
positive control
9
V1
NM_001033560.1
EXON1
2
3
4
5
6
7
8
8’
9
V1-1
NEW TRANSCRIPTS
EXON1
2
3
4
5
6
7
8
8’
9
V1-2
EXON1
2
3
4
5
6
7 7’
9
V1-3
EXON1
2
3
4
5
6
7
9
V1-4
AS2
S2
EXON1
2
3
4
5
6
7
8
9
V2
NM_001033559.1
AS2
S2
EXON1
2
3
4
5
6
NM_13081.2
7
8
Fig.3 Comparative analysis of HERV-H LTR-associated DYX1C1
transcripts (V1, V1-1, V1-2, V1-3, V1-4) in normal and tumor
tissue samples. G3PDH indicates the positive control.
9 10
V3
Fig. 3,4 - (b) RT-PCR was conducted three times and G3PDH was used as
a control. PCR products were analyzed quantitatively using the Image-J
program. The X-axis of the bar graph indicates normal (N)/tumor (T)
tissue samples. Lanes: M, size marker; 1, colon (N); 2, colon (T); 3, liver
(N); 4, liver (T); 5, uterus (N); 6, uterus (T); 7, breast (N); 8, breast (T); 9,
stomach (N); 10, stomach (C) and the Y-axis of the bar graph indicates
the relative expression levels of 2 transcripts (V2 and V3). P < 0.05 in
Student’s t-test is indicated by *.
Fig.5 Comparative analysis of the other transcripts (V2, V3)
in normal (N) and tumor (T) samples of colorectal cancer
patients. G3PDH indicates the positive control
The DYX1C1 gene is shown to have three alternatively
spliced transcripts in the GenBank database. V1, V2, and
V3 are the originally reported transcripts, and V1-1, V1-2,
V1-3, and V1-4 are newly identified alternative transcripts.
References
1. Adran A, Yoshida A, Ishikawa K, Goi T, Yamaguchi A, Ueda T, Inuzuka M. (2004) Identification of a novel splice variant of the human anti-apoptopsis gene survivin. Biochem Biophys Res
Commun. 314: 902-7.
2. Brinkman BM. (2004) Splice variants as cancer biomarkers. Clin Biochem. 37: 584-94.