(Received for publication, October 12, 1994)
From the
A-crystallin binding protein I (
A-CRYBP1) is a
ubiquitously expressed DNA binding protein that was previously
identified by its ability to interact with a functionally important
sequence in the mouse
A-crystallin gene promoter. Here, we have
cloned a single copy gene with 10 exons spanning greater than 70 kb of
genomic DNA that encodes
A-CRYBP1. The mouse
A-CRYBP1 gene
specifies a 2,688-amino acid protein with 72% amino acid identity to
its human homologue, PRDII-BF1. Both the human and the mouse proteins
contain two sets of consensus C
H
zinc fingers
at each end as well a central nonconsensus zinc finger. The
A-CRYBP1 gene produces a 9.5-kb transcript in 11 different tissues
as well as a testis-specific, 7.7-kb transcript.
A-CRYBP1 cDNA
clones were isolated from adult mouse brain and testis as well as from
cell lines derived from mouse lens (
TN4-1) and muscle
(C
C
). A single clone isolated from the muscle
C
C
library contains an additional exon near
the 5`-end that would prevent production of a functional protein if the
normal translation start site were utilized; however, there is another
potential initiation codon located downstream that is in frame with the
rest of the coding region. In addition, we identified multiple cDNAs
from the testis in which the final intron is still present. Finally, we
used an antisense expression construct derived from an
A-CRYBP1
cDNA clone to provide the first functional evidence that
A-CRYBP1
regulates gene expression. When introduced into the
TN4-1
mouse lens cell line, the antisense construct significantly inhibited
expression from a heterologous promoter that utilized the
A-CRYBP1
binding site as an enhancer.
A-CRYBP1 (
)is a DNA binding protein that was
identified by its ability to recognize the sequence 5`-GGGAAATCCC-3` at
position -66/-57 of the gene encoding mouse
A-crystallin, a protein expressed almost exclusively in the ocular
lens(1, 2) . Mutations in the
A-CRYBP1 binding
site caused significant reductions in
A-crystallin promoter
function in transient transfection assays, suggesting that factors that
bind to this site are likely to play a critical role in regulating
A-crystallin gene expression(1, 3) . A partial
2.5-kbp
A-CRYBP1 cDNA encoding the carboxyl-terminal portion of a
protein that contains two contiguous zinc fingers was isolated from a
mouse lens-derived cell line library(1) . DNA sequence analysis
revealed that
A-CRYBP1 is homologous to a rat protein, AT-BP2,
that interacts with the
-antitrypsin promoter (4) as well as to a human protein called PRDII-BF1, MBP-1, or
HIV-EP1, that binds to similar sequences in the interferon
gene
promoter(5) , the MHC H2-K
gene
promoter(6) , and the HIV-1 viral enhancer(7) ,
respectively. The peptide sequence of PRDII-BF1 inferred from
overlapping cDNAs revealed a 2,717-amino acid protein with one pair of
consensus zinc fingers near the amino terminus and a similar pair near
the carboxyl terminus corresponding to those in
A-CRYBP1(5) . The amino- and carboxyl-terminal zinc
fingers of PRDII-BF1 can independently recognize the same DNA binding
sites(5) . The
A-CRYBP1 transcript is approximately 9.5 kb
long in newborn mice, suggesting that the mouse gene encodes a protein
of comparable size with human PRDII-BF1(1) .
Aside from its
ability to bind to DNA in a site-specific manner, nothing is known
about the mechanisms by which A-CRYBP1 might regulate gene
expression in the mouse. In this report, we describe the cloning and
characterization of the mouse
A-CRYBP1 gene. We chose to clone the
gene for several reasons. First, the
A-CRYBP1/PRDII-BF1 binding
site is very similar to the recognition sequence of the transcription
factor NF-
B that has been implicated in the regulation of many
human and murine genes(8) , raising the possibility that some
of the promoters that are thought to interact with NF-
B might also
interact with
A-CRYBP1/PRDII-BF1. Studies of the
A-CRYBP1
gene may help to elucidate additional pathways of regulation for an
array of genes. Second, Kantorow et al.(9) showed
that an anti-
A-CRYBP1 antibody recognizes proteins of different
sizes on Western blots of mouse tissue culture cells, and Muchardt et al.(10) have identified alternatively spliced
transcripts of PRDII-BF1 by polymerase chain reaction in human cell
lines, suggesting that a thorough knowledge of the intron/exon
structure of the
A-CRYBP1 gene is necessary to determine if
alternative RNA splicing is involved in the generation of variant
A-CRYBP1 proteins with potentially different capabilities for
transcriptional regulation. Finally, obtaining a clone of the
A-CRYBP1 locus will allow us to selectively mutate this gene
through the process of homologous recombination in embryonic stem cells
followed by the incorporation of those stem cells into mouse
blastocysts(11) .
DNA fragments and oligonucleotides
used as hybridization probes for library screening were made
radioactive by random priming and end labeling according to standard
procedures(12) . Libraries were hybridized in 3 SSC,
0.3 M Na
citrate
2H
O, pH 7.0, 2%
Ficoll, 2% bovine serum albumin, 2% polyvinylpyrrolidone, 1% SDS, 0.05 M HEPES, and 0.018 mg/ml denatured salmon sperm DNA. After
hybridization, the filters were washed several times in 2
SSC.
Hybridization and washes were both performed at 65 °C when DNA
fragments were used as probes and at 55 °C when oligonucleotides
were used as probes. Oligonucleotides were synthesized on an Applied
Biosystems DNA synthesizer.
Genomic and cDNA clones were subcloned into pBluescript/SK- (Stratagene) and sequenced using Sequenase (version 2, U. S. Biochemical Corp.). DNA sequences were analyzed using version 7 of the University of Wisconsin Genetics Computer Group software package.
Figure 1:
Structure of
human PRDII-BF1, oligonucleotide probes derived from PRDII-BF1, and
partial sequence of the mouse cDNA clone CC-1. A, schematic
representation of PRDII-BF1. Zinc finger sequences (Z) and
acidic domains (A) are indicated by shaded and blackboxes, respectively. The locations of start and
stop codons are shown above the cDNA. Overlapping
oligonucleotides derived from the PRDII-BF1 cDNA sequence that were
used to screen a CC
muscle cell cDNA library
are shown below the PRDII-BF1 cDNA; the initiation ATG is underlined. B, 5`-terminal sequence of the
C
C
cell cDNA clone CC-1. Sequences in CC-1
that show similarity to the open reading frame of PRDII-BF1 are
conceptually translated below the nucleotide sequence. Amino
acids that are identical to PRDII-BF1 are underlined;
nucleotides that are inserted relative to the PRDII-BF1 cDNA sequence
are shaded. A conceptual translation of the inserted sequence
is shown in the two different reading frames (ORF1 and ORF2) that align
with the PRDII-BF1 open reading frame.
Figure 2:
Genomic Southern blot analysis of
A-CRYBP1-related sequences in various eukaryotic species. A blot
containing genome equivalents of EcoRI-digested DNA from the
indicated species was hybridized with the insert from the
A-CRYBP1
cDNA clone CC-1. The blot was exposed after an initial low stringency
wash (A) and then re-exposed after a high stringency wash (B).
Figure 3:
Restriction maps of A-CRYBP1 genomic
clones and intron/exon structure of the
A-CRYBP1 gene. Panel
A, restriction maps of lambda clones isolated from a DBA/2J mouse
genomic library (MG10-1, MG18-1, MG62-1, MG
4-2, and MG49-1) and from a 129SV mouse genomic library
(MG17-4). Shadedbars indicate the regions of
each clone that were sequenced. solidbars labeled
with Romannumeralsabove the maps represent
exons; the exon labeled with an asterisk in MG62-1 (exon
III) corresponds to the inserted sequence in the cDNA clone CC-1 (see Fig. 1B). Regions of overlap between clones are
indicated by verticaldottedlines. The
locations of the initiation and termination codons based on a
comparison with PRDII-BF1 are indicted in MG10-1/MG18-1 and
MG49-1, respectively. B indicates BamHI site. PanelB, intron/exon structure of the
A-CRYBP1
gene. Filledboxes correspond to protein coding
exons; the openbox represents a 5`-untranslated
exon; stippledboxes with Z and Aunderneath denote the locations of consensus zinc fingers
and acidic domains, respectively. The cDNA clones CC-1 and
pYTN8-1 that were used to isolate the genomic clones are shown
aligned with the corresponding portions of the
A-CRYBP1 gene. The
sizes of restriction fragments in EcoRI-digested mouse genomic
DNA that should hybridize to each exon in CC-1 are shown below.
In
addition to the clones shown in Fig. 3A, we obtained
three other overlapping genomic clones that hybridized to the pYTN-8
insert (data not shown). The sequences of these clones are very similar
to the 3`-end of A-CRYBP1 but contain a number of missense and
nonsense mutations that would occlude the production of a functional
protein. Further analysis of these clones revealed the presence of a
retroviral long terminal repeat 1,082 bp upstream of a termination
codon homologous to that in pYTN-8(1) . Therefore, it appears
that these three clones represent a partial or complete
A-CRYBP1
pseudogene.
Figure 4:
Alignment of the A-CRYBP1 and
PRDII-BF1 amino acid sequences. The protein sequences of
A-CRYBP1
and PRDII-BF1, derived from conceptual translations of DNA, were
aligned using the algorithm of Needleman and Wunsch (45) as
adapted by version 7 of the University of Wisconsin Genetics Computer
Group sequence analysis software. Verticallines indicate identical amino acids between the mouse (M) and
human (H) sequences. Amino acids corresponding to the inserted
sequence in Fig. 1B (exon III) were deleted from the
A-CRYBP1 sequence prior to alignment. Boxes indicate the
zinc finger domains identified by Fan and Maniatis(5) . Arrows indicate the locations of introns in the mouse
A-CRYBP1 gene, and the exons from which the
A-CRYBP1 peptide
sequence is derived are indicated by Romannumeralsabove the mouse sequence. Boldunderlines define stretches of acidic amino acids flanking the zinc finger
regions; a putative nuclear localization signal is also underscored with a thinnerline.
Figure 5:
Northern blot analysis of A-CRYBP1
message in adult mouse ovary and testis. A, a blot containing
20 µg of total RNA isolated from adult mouse ovaries (O)
and testes (Te) was hybridized with the insert from the
C
C
muscle cell line cDNA clone, CC-1. B, the blot was reprobed with the human
glyceraldehyde-3-phosphate dehydrogenase
cDNA.
Figure 6:
A-CRYBP1 cDNA clones. cDNA libraries
made from RNA isolated from
TN4-1 mouse lens-derived cells,
adult mouse brain, and adult mouse testes were screened with
restriction fragments encompassing the protein coding regions of
genomic clones MG4-2 and MG49-1 (Fig. 3A).
The top of the figure depicts the locations of exons above a
consensus
A-CRYBP1 cDNA. Note that exon III is present only in
CC-1. Z/A indicates the location of consensus zinc
finger/acidic domains; Z denotes the central nonconsensus zinc
finger. cDNA clones isolated from the brain (MBC1-13), testis
(MTC1-8), and
TN4-1 (p2A-5 and p4B-1) libraries are
represented by diagonalstripes, verticalstripes, and solidblack, respectively,
and are aligned with the consensus cDNA. Clone CC-1, isolated from
C
C
mouse muscle cells, and the initial
A-CRYBP1 cDNA clone, pYTN-8, are also shown. Sequences in cDNA
clones that are not present in the consensus cDNA are indicated by openbars.
All of the cDNA sequences except for the testis clones MTC-1, MTC-6, and MTC-7 can be clearly aligned with the ORF of PRDII-BF1 and show no evidence of alternative splicing relative to the human cDNA. The 3`-end of MTC-1 and the 5`-ends of MTC-6 and MTC-7 diverge from the PRDII-BF1 sequence and correspond exactly to the intron between exons IX and X (Fig. 3) that has been spliced out of the other overlapping cDNAs. This sequence is flanked by consensus donor and acceptor splice sites (17) and contains multiple stop codons that would result in the production of a truncated protein if present in the mRNA (data not shown).
In
addition to CC-1, we obtained two cDNAs (one of which was isolated
seven times) from the brain that encompass the 5`-end of the
A-CRYBP1 gene. Both of the brain cDNAs lack exon III, which is
found only in CC-1 (Fig. 1B and Fig. 3). Of the
three 5`-cDNAs, CC-1 contains the shortest stretch of 5`-untranslated
sequence, and this sequence is identical to that immediately preceding
the initiation codon in the genomic clones MG10-1 and
MG18-1 (Fig. 3). Comparison of the 5`-untranslated region
of MBC-1 with the MG10-1 genomic sequence reveals the presence of
a 3.3-kb intron located 104 bp upstream of the initiation ATG (Fig. 3). The sequence of the 5`-end of MBC-3,5,6,7,9,10,11
diverges from the genomic sequence downstream from this intron. The
5`-terminal sequence of this clone does not appear to be present in our
genomic clones based on both DNA hybridization experiments and direct
sequence comparisons. Furthermore, the point at which the genomic
sequence diverges from that of MBC-3,5,6,7,9,10,11 does not correspond
to a splice acceptor site (data not shown)(17) . Therefore, we
believe that the unidentified 5`-terminal sequence of
MBC-3,5,6,7,9,10,11 is a cloning artifact. The 5`-end of MBC-1 lies
within a region of genomic DNA in MG10-1 that is extremely rich
in guanosines and cytosines (data not shown). Attempts to verify the
5`-end of the
A-CRYBP1 message by primer extension have been
unsuccessful, probably as a result of RNA secondary structures that are
stabilized by these GC residues.
A comparison of the cDNA and
genomic clones indicates that the A-CRYBP1 gene comprises 10 exons (Fig. 2B). The cDNA clones show evidence for
alternative RNA splicing involving the third exon, which is present
only in CC-1, as well as differential splicing of the final intron,
which is present in three of the testis cDNA clones but not in any of
the other cDNAs that span this region. The introns separating the 10
A-CRYBP1 exons are all bounded by consensus splice donor and
acceptor sites (17) except for the intron that immediately
precedes exon VII with the carboxyl-terminal zinc fingers (Fig. 3). In this intron, the splice donor sequence is
``GC'' rather than the consensus ``GT''.
pCCRXN-1 was
transfected into TN4-1 mouse lens-derived cells, and stably
transformed cell lines were established by selection with G418. To
assay for reduced
A-CRYBP1 activity, the cells were transiently
transfected with plasmids containing either one (PCS-15) or four
(pCS-31) copies of the
A-CRYBP1 binding site placed upstream of
the herpes simplex virus thymidine kinase promoter which, in turn, was
fused to the bacterial CAT reporter gene. It was previously shown that
these reporter constructs produced significant levels of CAT activity
in transfected
TN4-1 cells and that the level of CAT
activity was directly proportional to the number of
A-CRYBP1
binding sites present in the construct(14) . In the present
experiments, we found that the pCCRXN-1 construct was not maintained
intact in stably transformed lines of
TN4-1 cells. A likely
explanation for this result is that the antisense construct was
poisonous to the cells, and only cells with deletions in the
A-CRYBP1 portion of the plasmid could survive the G418 selection
process.
To obviate the putative poisonous effect of the
A-CRYBP1 antisense construct, we measured CAT activity in
TN4-1 cells that were transiently cotransfected with
pCCRXN-1 and either of the two reporter constructs pCS-15 or pCS-31. Fig. 7shows CAT activity levels normalized to
-galactosidase activity from a cotransfected bacterial lacZ-expressing plasmid. In cells cotransfected with pTKCAT, a
reporter plasmid lacking the
A-CRYBP1 binding site, there was
almost no CAT activity irrespective of the presence of the antisense
construct (pCCRXN-1). Cells transfected with the pCS-15, which has one
A-CRYBP1 binding site, had low levels of CAT activity when
cotransfected with either the antisense (pCCRXN-1) or control
(pCDNA-1/Neo) plasmid, although there is a slight but statistically
significant reduction in CAT levels with the antisense plasmid. Cells
cotransfected with pCS-31, which contains four
A-CRYBP1 sites, and
the control plasmid (pCDNA-1/Neo) show almost 10 times as much CAT
activity as the cells transfected with pCS-15. When cells were
cotransfected with pCS-31 and the antisense-containing plasmid
(pCCRXN-1), CAT activity was reduced by approximately 50%. Therefore,
the
A-CRYBP1 antisense construct appears to have a significant
inhibitory effect on the activity of a promoter in which the
A-CRYBP1 binding site is the only enhancer element.
Figure 7:
A-CRYBP1 antisense experiments. CAT
activity levels normalized to
-galactosidase activity in
cotransfected
TN4-1 cells are shown for each set of
transfections.
TN4-1 cells were transfected with 1 µg of
the lacZ-expressing plasmid pCMV
(Clontech), 12 µg of
either the pCS-15 or pCS-31 reporter constructs, and 20 µg of
either pCDNA-1 or pCCRXN-1 (denoted as pCCR for simplicity).
CAT activity is expressed in counts/min/
-galactosidase activity.
-galactosidase activity was measured in absorbance units at A
. Each verticalbar represents an average of six separate transfections; the standard
errors are indicated on each bar.
The genomic and cDNA clones that we have isolated indicate
that the A-CRYBP1 protein is encoded by a gene with 10 exons
spanning greater than 70 kbp of DNA. Several other cDNAs have been
isolated from rat, human, and mouse that contain zinc fingers very
similar to those of
A-CRYBP1 and PRDII-BF1. The human cDNA, MBP-2,
encodes a 2,500-amino acid protein with two sets of zinc fingers spaced
comparably with those of PRDII-BF1(19) . However, MBP-2 lacks a
central, nonconsensus zinc finger, and although there are patches of
similarity between MBP-2 and PRDII-BF1 (Fig. 8), the overall
sequence identity between these two proteins is only 33%. A partial
cDNA clone, Rc-1, isolated from mouse cells encodes the
carboxyl-terminal portion of a protein with one set of
A-CRYBP1-like zinc fingers adjacent to a conserved acidic domain,
but the only similarity between the remainder of the encoded proteins
of the two mouse cDNAs is confined to a stretch of 37 amino acids (22) (Fig. 8). Partial cDNAs isolated from rat
(AT-BP1/AGIE-BP1) and human (KBP-1) appear to be homologous to MBP-2
and Rc-1, respectively(4, 23, 24) . Fig. 8also shows an alignment of the zinc finger sequences of
A-CRYBP1, PRDII-BF1, MBP-2, and Rc-1. The similarity between the
zinc finger sequences in Fig. 8is reflected in the ability of
the corresponding proteins to recognize the same DNA binding sites in
gel mobility shift
assays(1, 4, 5, 10, 21, 22, 23, 24) .
However, each of these proteins preferentially binds to specific DNA
sequences that differ for each protein. Possibly, several different
mammalian proteins have evolved from an ancestral
A-CRYBP1-like
protein, and during the course of evolution, these factors acquired
subtle variations in DNA binding specificity and, perhaps, changes in
their ability to interact with other transcription factors. Our genomic
hybridization data suggest that homologues of these genes might be
present in non-mammalian species. Structural and functional studies of
A-CRYBP1-like proteins from distantly related species may
elucidate the utility of having multiple factors that recognize related
DNA binding sites. Such studies may also reveal evidence for
co-evolution between these factors and the gene promoters with which
they interact.
Figure 8:
Comparison of mouse and human cDNA clones
that have related zinc finger sequences. The amino acid (a.a.)
sequences of human clones MBP-2 and PRDII-BF1 and mouse clones
A-CRYBP1 and Rc-1 were aligned using the algorithm of Needleman
and Wunsch (45) as adapted by version 7 of the University of
Wisconsin Genetics Computer Group. The regions of highest similarity in
the resulting alignments are indicated by the lines that
connect the paired cDNAs. The numbers represent the percentage
of amino acid sequence identity in each region. ZF/A indicates
zinc finger/acidic regions; ZF indicates a nonconsensus zinc
finger that is present in
A-CRYBP1 and PRDII-BF1 but not in the
other two cDNAs. The zinc finger sequences from each clone are aligned
at the bottom of the figure.
The intron/exon structure of the A-CRYBP1 gene
has several interesting features. The first is the presence of exon III
that is found only in the one cDNA clone, which was isolated from the
C
C
muscle cell line library. The inclusion of
exon III sequences in mRNAs would prevent the formation of a functional
protein if the normal translation start site were utilized. There is
another ATG, located further downstream, that is in the same ORF as the
rest of the
A-CRYBP1 protein coding sequence. However, other
studies have shown that reinitiation of translation at downstream ATGs
usually occurs with very low efficiency(25) . Perhaps the
inclusion of exon III sequences by alternative splicing serves to
modulate the amount of
A-CRYBP1 protein without changing the level
of mRNA. There are precedents for employing alternative exons as a
means of down-regulating protein expression. For example, the Drosophila sex-lethal gene produces a male-specific transcript
containing an in-frame stop codon that results in a non-functional
protein only in male flies(26) , and a majority of the
transcripts produced by the cH-ras gene contain an extra exon
that leads to the production of a truncated, non-functional
protein(27) . The C
C
cell culture from
which the cDNA library was constructed consisted largely of
differentiating myoblasts. (
)It has been shown that
C
C
cells undergo extensive changes in gene
expression during differentiation into myotubes(28) , and it is
possible that a reduction in
A-CRYBP1 levels may be necessary for
affecting some of these changes.
The large size of A-CRYBP1
exon V is another striking feature of the
A-CRYBP1 gene. The
average vertebrate exon size is 137 nucleotides, and very few are
greater than 600 nucleotides in length(29) . However, it has
been recently shown that increasing the size of an exon in vivo does not necessarily interfere with RNA splicing(30) . In
light of the belief that many genes have evolved by a process of exon
duplication and shuffling(31) , exon V may represent the
structure of an ancestral
A-CRYBP1 gene. The recruitment of the
other smaller exons during the course of evolution might have occurred
to alter or extend the functional role of the
A-CRYBP1 protein in
regulating gene expression as postulated above for differentiating
myoblasts.
It is also interesting that the second (3`) set of zinc
fingers in A-CRYBP1 is encoded by a separate exon, and the
nucleotides corresponding to the acidic domain adjacent to these
fingers are located on yet another exon. This structure imbues the
A-CRYBP1 gene with the potential flexibility to produce
functionally distinct protein isoforms via alternative splicing of
these two domains. In addition, the intron that immediately precedes
the carboxyl-terminal zinc finger-containing exon (exon VII) has a
nonconsensus 5`-splice site in which ``GC'' replaces the
almost universal ``GT'' at this position(17) . The
mouse
A-crystallin gene also has an intron with the same
noncanonical 5`-splice site(32) . In the case of
A-crystallin, the intron is spliced inefficiently, resulting in
two forms of the
A-crystallin protein that differ by the presence
or absence of the exon that precedes the aberrant splice site.
None
of the cDNA clones that we isolated showed evidence of differential
splicing involving the zinc finger domains. There are multiple, cell
type-specific forms of A-CRYBP1 as judged by Western blots where
an antibody specific for the carboxyl-terminal half of
A-CRYBP1
recognizes 50-, 90-, and 200-kDa proteins, which may involve
alternative RNA splicing in those cell lines(9) . Moreover,
Muchardt et al.(10) detected in human cells, using a
sensitive polymerase chain reaction technique, rare PRDII-BF1
transcripts that contained only the amino- or the carboxyl-terminal
zinc fingers. One of these transcripts results from a deletion in which
a nucleotide corresponding to bp 13 of
A-CRYBP1 exon VI is joined
to the sequence beginning with nucleotide 204 in
A-CRYBP1 exon IX.
The other transcript contains a deletion corresponding exactly to exon
V of
A-CRYBP1. These results also suggest that there is at least
some conservation of exon structure between the mouse gene and its
human homologue that has not yet been isolated.
The testis-specific
transcript described for the rat AT-BP2 gene (4) is also
produced by the A-CRYBP1 gene in the mouse. A number of other
mammalian genes produce different sized mRNAs that are detected only in
the testis. These messages may arise from testis-specific sites of
transcription
initiation(33, 34, 35, 36) ,
polyadenylation(37, 38) , or alternative
splicing(39, 40, 41) . In several cases, it
has been demonstrated that the testis-specific transcript is produced
specifically by spermatogenic
cells(37, 40, 42) . We isolated a number of
A-CRYBP1 cDNA clones from a mouse testis library. Three of these
clones were derived from mRNAs in which the last intron had not been
removed. Since the testis-specific transcript observed on Northern
blots is smaller than the ubiquitous
A-CRYBP1 transcript, there
must be another difference between the two mRNAs that is not reflected
in the cDNAs that we isolated.
The antisense experiments provide
direct functional in vivo evidence that A-CRYBP1 is
involved with regulating gene expression via the promoter sequence
GGGAAATCCC. Although the antisense construct produces a significant
decrease in CAT activity, there is still a substantial amount of CAT
activity remaining in the cotransfected cells. This residual CAT
activity probably results, in part, from incomplete inhibition of
A-CRYBP1 by the antisense message, but it might also reflect the
ability of other proteins to regulate transcription through this
10-base pair sequence. Besides the related zinc finger proteins
mentioned above, NF-
B and members of the c-rel family of
transcription factors bind to a consensus sequence (GGGRNNYYCC) that
corresponds to the site in our reporter constructs(8) .
Furthermore, the promoter sequence, PRDII, to which PRDII-BF1 binds in
the human interferon-
gene, is recognized by at least five
different factors including NF-
B, PRDII-BF1, and HMG I(Y) (43, 44) . However, our experiments provide the first
functional evidence that
A-CRYBP1 is at least one of the proteins
that is involved in regulating gene expression using this sequence from
the promoter of the mouse
A-crystallin gene.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBank(TM)/EMBL Data Bank with accession number(s) L36825[GenBank]-L36829[GenBank].