(Received for publication, September 25, 1996)
From the La Jolla Cancer Research Center, The Burnham Institute, La Jolla, California 92037
The PR domain is a newly recognized protein motif
that characterizes a subfamily of Krüppel-like zinc finger genes.
Members of the PR domain family have been shown to play important roles in cell differentiation and malignant transformation. The RIZ gene is
the founding member of this family; it was isolated because its gene
products can bind to the retinoblastoma tumor suppressor protein. Here,
we have studied the RIZ gene structure and expression. By
immunoprecipitation and immunoblot analysis we identified two different
RIZ protein products of 280 and 250 kDa, designated RIZ1 and RIZ2,
respectively. The 280-kDa RIZ1 product comigrated with the RIZ
cDNA-derived polypeptide. The 250-kDa RIZ2 product lacked the
NH2-terminal PR domain of RIZ1; it comigrated with a
truncated RIZ1 polypeptide that was initiated from an internal ATG
codon. Both the full-length and the truncated RIZ1 polypeptide were
located in the nucleus as shown by transfection and immunofluorescence analysis. We identified the RIZ2 transcripts and showed that they were
produced by an internal promoter located at the 5 boundary of coding
exon 5. RNase protection analysis revealed similar ratios of RIZ1 and
RIZ2 transcripts in most adult rat tissues except in testis, where RIZ1
was more abundant than RIZ2. These observations were strikingly similar
to those described for the MDS1-EVI1 cancer gene, which
also normally gives rise to a PR domain-lacking product, EVI1, because
of an internal promoter.
The Krüppel-like family of zinc finger genes is estimated to consist of hundreds of human genes (1). A number of them are involved in human diseases especially cancer, including BCL6, PLZF, EVI1, and WT1, to name a few (2-5). This family is characterized by the Cys2-His2 zinc fingers and can be divided further into different subsets based on other structural features, which include the seven-amino acid H/C link between adjacent fingers (6) and several conserved NH2-terminal modules (7-11).
The PR domain is a newly recognized NH2-terminal module. It was first noted during our characterization of the RIZ gene and was named for the homologous 100-amino acid region shared between RIZ and the PRDI-BF1/BLIMP1 transcription repressor that promotes B lymphocyte maturation (12-15). The RIZ gene was isolated because its gene products can bind to the retinoblastoma protein, a tumor suppressor known to function in gene expression through physical interaction with transcription factors (16, 17). The predicted rat and human RIZ proteins are of 1,706 and 1,719 amino acids, respectively, and are highly homologous (84% amino acid identity). Besides the zinc fingers, several other interesting motifs are also found in RIZ, including a region of homology to E1A, a GTPase motif, and an SH3 motif. Partial or variant human cDNA clones of RIZ have since been isolated using different strategies. One of these is termed GATA-3-binding protein G3B, which was isolated by functional screening using GATA-3 transcription factor protein as probe (18). Another is termed MTB-Zf, which was isolated through binding to the DNA element GTCATATGAC responsible for the induction of human heme-oxygenase-1 gene during 12-O-tetradecanoylphorbol-13-acetate-induced differentiation of myelomonocytic cell lines (19). Together, these findings suggest that RIZ may function as a DNA-binding transcription factor.
The RIZ gene has been mapped to human chromosome band 1p36 near the marker D1S228 and the syntenic region in mouse chromosome 4 (19-21). Deletion and alteration of the 1p36 region are commonly found in a variety of human cancers, including neuroblastoma, hepatoma, and breast cancer. Recently, we showed that a known cancer gene, MDS1-EVI1, shares PR domain homology with RIZ (22). We also mapped the human PRDI-BF1/BLIMP1 gene to D6S447 on chromosome band 6q21-q22, a region commonly altered in B cell non-Hodgkin lymphoma and melanoma (23). These observations suggest that PR domain genes may play an important role in human cancer.
To help understand the function of RIZ, we have here further characterized its gene products. Previously, we have identified a 250-kDa RIZ protein in rat and human cells (13). We now show that this 250-kDa protein lacks the PR domain; we identified the full-length RIZ protein to be of 280 kDa. We show that transcripts for the 250-kDa protein were generated by an internal promoter. The finding revealed striking similarity between RIZ and the MDS1-EVI1 cancer gene.
Rat B50 cells, human HT1080
fibrosarcoma cells, Y79 retinoblastoma cells, and SAOS2 osteosarcoma
cells were grown in Dulbecco's modified Eagle's medium plus 10%
fetal calf serum. NIH 3T3 cells were grown in Dulbecco's modified
Eagle's medium plus 10% calf serum. For transfections of these cells,
a calcium phosphate precipitation procedure was used (24). Cells were
processed 36 h after withdrawal of DNA for immunoprecipitation,
immunofluorescence, or chloramphenicol acetyltransferase
(CAT)1 analysis. For normalization of
transfection efficiencies in 3T3 cells, a -galactosidase expression
construct (pCMV-LacZ) was included in the cotransfections. CAT activity
and the level of
-galactosidase expression were determined as
described (25). Cell line HCR1, which stably expressed the
cDNA-derived rat RIZ protein, was generated by G418 selection of
pCMVRIZ-transfected human HT1080 cells.
Monoclonal antibody 2D7, mouse serum KGSE, and rabbit serum KG7.1S have been described previously (13). The monoclonal antibody P4E1 was generated by injecting mice with the glutathione S-transferase-PR domain (rat) fusion protein KGPR.
Immunoprecipitation and immunoblot were performed as described previously (13). Briefly, cells were lysed in ELB lysis buffer (250 mM NaCl, 0.1% Nonidet P-40, 50 mM Tris-HCl, pH 7.0). Cell extracts were incubated with RIZ serum (anti-KG7.1S) for 1 h followed by 1 h of incubation with protein A-Sepharose at 4 °C. Proteins bound to protein A-Sepharose were washed four times with ELB and were analyzed on 5% SDS-polyacrylamide gel. Immunoblot was performed on Immobilon P filters (Millipore) using RIZ monoclonal antibodies P4E1 or 2D7 or mouse serum KGSE and alkaline phosphatase-conjugated goat anti-mouse IgG.
Immunofluorescence staining was performed on transfected SAOS2 cells seeded on a glass coverslip. After transfection, cells were washed in phosphate-buffered saline and fixed in methanol for 2 min on ice. Cells were then incubated with 2D7 antibody for 1 h in phosphate-buffered saline plus 4% milk. After washing 3 times with phosphate-buffered saline, the cells were further incubated for 1 h with fluorescein isothiocyanate-conjugated goat anti-mouse IgG. Cells were then washed with phosphate-buffered saline, stained for DNA with 0.5 µg/ml of DAPI, mounted, and examined using an epifluorescent microscope equipped with filters allowing discrimination between the fluorescein isothiocyanate (RIZ) and DAPI (all cells).
cDNA and Genomic DNA CloningThe 5 region of human RIZ
cDNA was cloned by rapid amplification of cDNA ends using the
Marathon ready cDNA from human fetal brain (Clontech) according to
the manufacturer's recommended procedures. The primer RP198 from
nucleotide 823 to 852 was used:
5
-CCGGATCCAATTCCTGTTGTGTTCTGTAAAGATACA-3
. The 3
region was cloned
and characterized using IMAGE consortium cDNA clones 40662 and
163778 whose Expressed Sequence Tag sequence (GenBank accession nos.
R56425[GenBank] and H14131[GenBank]) overlapped with the previously published RIZ
cDNA coding sequence (26).
The chromosome 1 cosmid library from the Reference Library Data base at
the Max Plank Institute in Berlin (27) was screened using a human RIZ
cDNA probe according to procedures recommended by the supplier.
Partial rat RIZ gene was isolated from a rat genomic library
(Clontech) and from a rat testis cDNA library (Stratagene) that
contained incompletely spliced cDNA. Partial mouse RIZ gene was
isolated from 129SVJ
genomic library (Stratagene). The DNA sequence
was determined using Sequenase (U. S. Biochemical Corp.) and
oligonucleotide primers.
To generate the plasmid pKGPR for production of a glutathione S-transferase-PR domain fusion protein, a HindII-StuI fragment (amino acids 37-214) of rat RIZ cDNA was cloned into the NcoI site of pKG-GEX vector. The fusion was confirmed to be in-frame by DNA sequencing analysis.
We have previously generated an EE epitope-tagged rat RIZ cDNA
expression plasmid pCMVRIZ (13). To express a more authentic RIZ
protein lacking the EE tag, the tagged RIZ cDNA was first moved
from pCMVRIZ to the vector pcDNA3 by the HindIII and
NotI cloning sites to generate pcRIZEE. A PCR fragment of
0.7 kb starting from the first Met residue was synthesized using the
antisense primer RP9: 5-ATCTACCTCTGGCTGTGGCTCGCA-3
and the forward
primer RPNco, which introduced an NcoI site at the position
of the first Met: 5
-GCCGCCATGGATCAGAACACTGAGTCTGTG-3
. The PCR
fragment was then cleaved with NcoI and StuI and
was used to replace the corresponding fragment in pcRIZEE to produce
p3RIZr. The PCR fragment was confirmed by DNA sequence analysis. p3RIZr
contains the full-length coding region of rat RIZ cDNA, which
differs from the wild type sequence by only one nucleotide at the
second amino acid position, changing the histidine residue into
aspartic acid. To generate the p3RIZrKK plasmid that deleted the region
of 1-92 amino acids, p3RIZr was cut with HindIII and Kpn21
followed by Klenow treatment and self-ligation.
For generation of antisense human RIZ RNA probe, an reverse
transcriptase PCR fragment was synthesized using Y79 retinoblastoma cell mRNA and primers RP96 (5-ATGAATCAGAACACTACTG-3
) and RP102 (5
-CTTCTGCAGAATCTCTCA-3
). This fragment contains the region from the
first Met to the end of exon 7 and was cloned into the SrfI
site in pCR-Script (Stratagene) to generate pCR96-102. Antisense RNA
can be produced by T3 RNA polymerase.
For the antisense rat RIZ RNA probe, the plasmid pSK12.1SX was
generated, which contained a 5 end fragment of 0.7 kb of rat cDNA
cloned into pBluescript. Antisense RNA was produced by T3 RNA
polymerase.
For promoter analysis, a 3.5-kb genomic DNA fragment containing intron
5 and exon 6 was first cloned into pBluescript to generate pSK5X. A PCR
fragment was amplified from pSK5X using primer RP186 (5-CGGCAAGCTTCGCCGACAGCTGTTTGCCATC-3
) and primer RP174
(5
-TCCTACCTTTCCGGCTCTTC-3
). The PCR fragment was cloned into the
HindIII and XhoI sites in pBLCAT3 vector (28) to
generate pCAT186. To construct exon 6 deletion mutant pCAT186S, pCAT186
was cleaved with SacI, and the large fragment was
self-ligated.
RNA was prepared using RNazol according to the manufacturer's recommended procedures (Tel-Test, Inc.). 20-30 µg of total RNA was used for protection analysis as described (25). Antisense human RNA probe was generated by T3 RNA polymerase and [32P]UTP using ApoI- or BglII-restricted plasmid pCR96-102. Antisense rat RNA probe was generated by T3 RNA polymerase using AccI-restricted plasmid pSK12.1SX. An equal amount of yeast tRNA was used as negative control. The protected products were analyzed on DNA sequencing gel.
For primer extension analysis of human mRNA, the antisense oligomer
RP171 was synthesized, which corresponds to amino acid residues
179-168: CCTGGGATTTTTTCTTCCCTTTCCGGCTCTTGGG. The primer was end
labeled with [-32P]ATP and polynucleotide kinase.
Extension reaction was performed on 30 µg of BALL1 RNA using Moloney
murine leukemia virus reverse transcriptase (New England Biolabs)
according to standard procedures (25). Yeast tRNA was used as a
negative control. Extension products were analyzed on DNA sequencing
gel followed by autoradiography.
To identify
cellular RIZ protein products, rat brain tumor B50 cell extracts were
immunoprecipitated with a rabbit serum directed against a recombinant
RIZ protein KG7.1S (residues 245-573). The immunoprecipitated proteins
were analyzed by immunoblot using the monoclonal antibody 2D7 specific
for the rat RIZ protein (amino acids 215-244). As shown in Fig.
1, two protein products of 250 and 280 kDa were
specifically recognized by the RIZ antibodies. The identification of
the 250-kDa protein has been described; the 280-kDa protein has also
been noted previously but was not characterized (13). Protein products
of identical size were also found in human Y79 cells by immunoblot
using mouse antiserum KGSE (13). That these proteins could be
recognized by two different RIZ antibodies suggests that they are
candidate cellular RIZ protein products. Also, the 280-kDa protein
could be recognized by another monoclonal antibody, P4E1 (see
below).
To show that our full-length RIZ cDNA could encode a 280-kDa
protein, we transfected into human HT1080 cells an expression construct
of rat cDNA p3RIZr. The transiently expressed protein was analyzed
by immunoprecipitation and immunoblot as described above. The results
showed that the cDNA-derived RIZ protein product comigrated with
the cellular 280-kDa protein (Fig. 2A). We
have also established a human HT1080-derived cell line HCR1, which stably expressed the exogenous rat RIZ protein; this protein also comigrated with the cellular 280-kDa protein (Fig. 2B).
If the 280-kDa protein is the full-length RIZ gene product, what might be the structure of the 250-kDa protein? We examined whether it might represent an internally initiated, truncated version of RIZ1. We first determined whether a 250-kDa protein can be produced by internal initiation. Because the 250-kDa protein could be recognized by the monoclonal antibody 2D7, which reacts with an epitope within residue 215-244 (13), the putative internal initiation codon must be located within the first 244-amino acid region. There are three in-frame internal ATGs within this region which are conserved among rat, mouse, and human; the third one at codon 201 in rat (202 in human) shows the best Kozak consensus sequence: AACATGA (rat and mouse) or AATATGA (human) (13). To determine whether ATG201 could serve as an initiation codon, we made a construct p3RIZrKK, which deleted residues 1-92 containing the normal initiation codon and the first two internal ATG codons. As shown in Fig. 2A, upon transient transfection of p3RIZrKK into human HT1080 cells, a polypeptide was produced which was recognized by 2D7 and comigrated with the cellular 250-kDa RIZ. The recognition of the recombinant polypeptide by 2D7 shows that ATG201, rather than a downstream ATG, must be the initiation codon for it. The result further suggests that ATG201 is the most likely initiation codon for the cellular 250-kDa RIZ protein if it is to be produced from internal initiation; the other two candidate ATG codons are ~100 residues upstream and are expected to give rise to a distinguishably larger product in SDS gels.
We next examined whether the 250-kDa cellular protein might indeed lack the NH2-terminal region of full-length RIZ1. We generated a monoclonal antibody P4E1 that was raised against the NH2-terminal PR domain region (residue 37-214) of the rat RIZ protein. Cell extracts from rat B50 cells and HCR1 cells were immunoprecipitated by RIZ serum (KG7.1S), and the immunoprecipitated proteins were analyzed by immunoblot using either 2D7 or P4E1 monoclonal antibody. As shown in Fig. 2B, although both proteins could be recognized by 2D7, only the 280-kDa protein was recognized by P4E1, suggesting that the 250-kDa protein lacks the NH2-terminal PR domain region. Taken together with the above described results, the data were consistent with internal initiation for the 250-kDa cellular protein. We will hereafter call the 280-kDa polypeptide RIZ1 and the 250-kDa polypeptide RIZ2.
We have shown previously that the 250-kDa cellular RIZ2 protein is a
nuclear protein (13). To confirm this, we determined whether the
cDNA-derived 250-kDa protein is also a nuclear protein. The 250-kDa
construct p3RIZrKK and the 280-kDa construct p3RIZr were transfected
into SAOS2 cells seeded on glass coverslips. The cells were analyzed by
immunofluorescence using 2D7 monoclonal antibody. Nuclear staining was
observed in either p3RIZr or p3RIZrKK transfected cells but not in
pcDNA3 vector transfected cells, suggesting that both the 280-kDa
and 250-kDa products are located in the nucleus (Fig.
3).
The RIZ2 Promoter
The above data showed that an internal initiation codon of RIZ1 was capable of initiating the synthesis of a 250-kDa polypeptide. Is this how RIZ2 actually generated in nature? Could RIZ2 be produced from the same transcript that gives rise to the 280-kDa RIZ1 polypeptide? Although ATG201 can serve as an initiation codon when placed as the first in-frame ATG, could it also do so in the context of RIZ1 transcript where it would be the fourth in-frame ATG? The data shown in Fig. 2B suggest that this is unlikely; the full-length cDNA produced only the 280-kDa product. The same data also suggest that proteolytic cleavage is unlikely involved in generating RIZ2.
The data were consistent with the existence of RIZ2-specific
transcripts. To study this further, we performed RNase protection analysis. An antisense RIZ probe was synthesized by T3 polymerase on
the ApoI-restricted plasmid pBSK96-102. This probe covered the region between amino acids 111 and 208 of the human cDNA. As
shown in Fig. 4A, we found three major
protected fragments by RNA from human B cell acute lymphoblastic
leukemia line BALL1, indicating three different RIZ transcripts.
Although the longest, full-length protected fragment of ~284
nucleotides represented RIZ1, the smaller fragments of 172 and 155 nucleotides might represent RIZ2-specific transcripts. The same size
smaller fragments were also observed when using a 3 extended longer
antisense probe (generated from BglII-restricted plasmid
pBSK96-102), showing that they were derived from the 5
portion of the
probe. The results suggested that the 5
ends of the putative RIZ2
transcripts were covered by these antisense probes and mapped to amino
acid residue 156 and 150. Identical results were also found in several
other human cell lines and tissues (not shown). We also analyzed rat tissue RNA using rat cDNA-derived probe and observed similar
results (see below). The presence of the smaller transcripts was also confirmed by primer extension analysis (Fig. 4B). An
antisense oligomer starting at residue 179 was used for the extension
reaction using BALL1 RNA. Two major extended products of 63 and 87 nucleotides were observed, indicating that these transcripts started at
amino acid residues 144 and 156, which was in general consistent with the result of RNase protection analysis. We concluded that transcripts specific for the RIZ2 protein are normally expressed in the cells that
contain ATG201 (rat) or ATG202 (human) as the first in-frame initiation
codon.
We next examined how these RIZ2 transcripts might be generated. We
first partially characterized the genomic DNA of the human, mouse, and
rat RIZ gene. We isolated the full-length human RIZ cDNA
of 7,943 nucleotides through 5 rapid amplification of cDNA ends
and making use of the Expressed Sequence Tag data base (dbest) and the
IMAGE consortium cDNA clones (26). The cDNA was then used to
screen the chromosome 1-specific cosmid library (27). We found that the
human RIZ cDNA was encoded by 10 exons (Fig. 5). The
exon structures of the 5
-coding regions of mouse and rat cDNAs
were also analyzed and were found to be identical to human. Based on
this organization of exons, the smaller transcripts as revealed by
RNase protection and primer extension analysis all have their 5
ends
located in the middle of exon 6 or coding exon 5 (Fig.
6). Because these transcripts did not start at the exon
boundary, they appear unlikely to be generated by alternative splicing.
If these transcripts were to be generated by alternative promoter,
their 5
ends must be located within exon 6. We would predict that a
promoter might exist near the boundary of intron 5 and exon 6.
To prove this prediction, we characterized the human, mouse, and rat
genomic DNA containing the boundary of intron 5 and exon 6. Sequence
analysis of the region revealed three boxes of sequences which are
conserved among species (Fig. 7). These conserved boxes are located within 100 base pairs of the boundary and include putative
binding sites for several transcription factors such as SP-1, WT1,
EGR1, C/EBP, and other CCAAT-binding proteins, and E-box binding
proteins (29, 30). The region is typically GC-rich; no TATA box was
found. The observation of at least two different length transcripts as
shown by RNase protection and primer extension analysis was also
consistent with a TATA-less promoter, many of which are known to
initiate transcription at multiple sites. Further, we have found in
exon 6 the consensus sequence of MED-1 (ultiple start site
lement
ownstream) GCTCCC/G, recently
described for those TATA-less promoters with multiple start sites (31).
These sequence features therefore predict a TATA-less promoter at the boundary of intron 5 and exon 6.
To show activity for this putative promoter, we generated the pCAT186
plasmid, which contained the conserved elements of intron 5 and the
intact exon 6 linked to the CAT gene. Strong CAT activity was observed
when pCAT186 was transfected into 3T3 cells (Fig. 8).
The corresponding fragment of rat genomic DNA also conferred promoter
activity (not shown). Deletion of part of exon 6 (pCAT186S) abolished
promoter activity.
Having identified the RIZ2 promoter and its transcripts, we next
determined whether the relative level of RIZ1 and RIZ2 mRNA may
vary among different cell types. We examined a number of rat tissues by
RNase protection analysis; the pattern given by rat tissue RNA was
similar to that of human RNA (Fig. 9). A similar ratio
(1:1) of RIZ1 to RIZ2 transcripts was found in most tissues examined
including brain, heart, skeletal muscle, kidney, liver, and spleen. The
pattern found in testis was unique where RIZ1 transcript was at a
5-10-fold higher level then RIZ2.
In this paper we showed that the RIZ gene encodes a full-length protein product of 280 kDa and an alternative smaller product of 250 kDa, designated RIZ1 and RIZ2, respectively. Both products could be recognized by three different antibodies, rabbit serum KG7.1S, mouse serum KGSE, and monoclonal 2D7, which were raised against two different regions of RIZ. RIZ1 was also recognized by the monoclonal P4E1 directed against the NH2-terminal PR domain region of RIZ1. RIZ2 was not recognized by P4E1, suggesting that it lacks the NH2-terminal region of RIZ1. Also, the protein product expressed from the full-length RIZ cDNA comigrated with RIZ1, whereas a PR domain-deleted mutant cDNA with ATG201 serving as the first in-frame initiation codon produced a protein that comigrated with RIZ2. The data suggest that RIZ2 lacks the PR domain of RIZ1.
We investigated the mechanisms of production of RIZ2. We showed that internal initiation from the RIZ1 transcript and proteolytic cleavage of RIZ1 were unlikely involved because the transfected full-length RIZ1 cDNA only produced the RIZ1 protein. Accordingly, we identified RIZ2 transcripts by RNase protection and primer extension analysis. These transcripts contain ATG201 in rat or ATG202 in human as the first in-frame initiation codon and are likely to be responsible for the synthesis of RIZ2 protein.
To understand the production of RIZ2 transcripts, we characterized the
exon structures of RIZ gene. We isolated a full-length human RIZ
cDNA of 7.942 kb which is comparable to the size of the largest
species of RIZ mRNA as estimated by Northern blot (19 and data not
shown). This cDNA is encoded by 10 exons and about 150 kb of
genomic DNA.2. It remains to be determined
whether the complete 5-untranslated region has been isolated. Most of
the coding region is within the largest exon, exon 8. The PR domain is
encoded by three small exons, exons 4-6. The exon structures of the
5
-coding region of rat and mouse cDNA were found to be identical
to human. RNase protection and primer extension analysis placed the 5
ends of RIZ2 transcripts in the middle of exon 6 (or coding exon
5).
We identified a promoter at the boundary of intron 5 and exon 6 which generates the RIZ2 transcripts. A ~240-base pair fragment that contains exon 6 and the conserved intron 5 sequence was able to confer promoter activity. This promoter lacks TATA box and is GC-rich; it also contained the MED-1 motif that characterizes many TATA-less promoters with multiple start sites (31). Exon 6 was shown to be required for promoter activity. The role of exon 6 may be to provide transcription start sites and the MED-1 motif. However, the precise role of the MED-1 motif and other conserved elements remains to be determined.
We note that the human MTB-Zf protein represents a variant of RIZ2. It
is identical to RIZ2 except at its last 4 amino acids, and it is 36 amino acids shorter at the COOH terminus. The difference starts at the
beginning of exon 9 and includes the whole 3-untranslated region,
suggesting that MTB-Zf is generated by alternative splicing of exons 9 and 10. The 5
end of MTB-Zf cDNA has been confirmed to be
full-length by primer extension analysis (19) and corresponds to amino
acid residue 142 located within exon 6 of RIZ1. This is consistent with
our mapping of the 5
ends of RIZ2 transcripts to residues 144-156.
The MTB-Zf variant may be particularly abundant in certain cells such
as THP-1 cells from which it was isolated. Future work will be needed
to determine the relative abundance of this variant among different
cell types. We predict that this variant, essentially a minor deletion
at the RIZ2 COOH terminus, will be indistinguishable from RIZ2 protein
in SDS gels. It will be of interest to determine whether they might
function differently.
The organization and expression pattern of the RIZ gene as shown by the
present study are strikingly similar to those of the MDS1-EVI1 gene. This gene was originally identified as two
separate genes, MDS1 and EVI1. MDS1
was cloned as one of the partner genes of AML1 in the t(3;21)
(q26;q22), associated with therapy-related acute myeloid leukemia and
myelodysplastic syndrome as well as with chronic myeloid leukemia in
blast crisis (32). The protooncogene EVI1 was first
identified in the mouse and is activated in murine myeloid leukemia by
proviral insertion in the EVI1 common integration site (4).
In humans the expression of this gene can be activated in myeloid
leukemias and myelodysplastic diseases by chromosomal rearrangements at
either 5 or 3
of the gene (32-34). Activation of EVI1 can
also occur as part of the fusion mRNA, AML1-EVI1 or AML1-MDS1-EVI1.
Abnormal expression of EVI1 has also been detected in
patients with myeloid leukemia and cytogenetically normal karyotype (35).
The MDS1-EVI1 fusion gene encodes an intact PR domain,
wherein MDS1 encodes one-third of the PR sequence and EVI1 the
remaining two-thirds (22). The EVI1 transcript is generated
by an internal promoter within the MDS1-EVI1 gene (36). An
in-frame internal ATG codon just 3 of the PR domain in
MDS1-EVI1 becomes the first ATG and the initiation codon in
the EVI1 transcript. Thus, the MDS1-EVI1 gene can produce at
least two different products, MDS1-EVI1 and EVI1,
which are differentiated by the PR domain. The EVI1 gene,
but not the MDS1-EVI1 gene, may function to promote
transformation as it is often overexpressed in leukemia cells.
The similarity between RIZ and MDS1-EVI1 as shown by this study further raises interest in the function of PR domain and the role of RIZ as a candidate cancer gene located on 1p36. What functional difference could the PR domain make between RIZ1 and RIZ2 or between MDS1-EVI1 and EVI1? Apparently, it was not involved in the nuclear localization of either gene product. Given the example of deregulation of EVI1 expression as a consequence of 3q26 abnormalities, could deregulation of RIZ1 or RIZ2 expression also occur in human cancer as a consequence of 1p36 abnormalities? This study should provide the means and reagents for addressing these important questions.
We thank Dr. Inge Buyse for plasmid constructions and Dr. B. K. Seon for the BaLL1 cell line.