By
From the * Institut de Recherches Cliniques de Montréal, Faculté de Médecine de l'Université de
Montréal, Montréal, Québec, Canada H2W 1R7; and Department of Pathology, College of
Physicians and Surgeons of Columbia University, New York 10032
The SBM mouse is a unique transgenic model of polycystic kidney disease (PKD) induced by
the dysregulated expression of c-myc in renal tissue. In situ hybridization analysis demonstrated
intense signal for the c-myc transgene overlying tubular cystic epithelium in SBM mice. Renal
proliferation index in SBM kidneys was 10-fold increased over nontransgenic controls correlating with the presence of epithelial hyperplasia. The specificity of c-myc for the proliferative potential of epithelial cells was demonstrated by substitution of c-myc with the proto-oncogene c-fos or the transforming growth factor (TGF)- within the same construct. No renal abnormalities were detected in 13 transgenic lines established, indicating that the PKD phenotype
is dependent on functions specific to c-myc. We also investigated another well characterized
function of c-myc, the regulation of apoptosis through pathways involving p53 and members
of the bcl-2 family, which induce and inhibit apoptosis, respectively. The SBM kidney tissues,
which overexpress c-myc, displayed a markedly elevated (10-100-fold) apoptotic index. However, no significant difference in bcl-2, bax, or p53 expression was observed in SBM kidney
compared with controls. Direct proof that the heightened renal cellular apoptosis in PKD is not
occurring through p53 was obtained by successive matings between SBM and p53
/
mice. All
SBM offspring, irrespective of their p53 genotype, developed PKD with increased renal epithelial apoptotic index. In addition, overexpression of both bcl-2 and c-myc in double transgenic mice (SBB+/SBM+) also produced a similar PKD phenotype with a high apoptotic rate,
showing that c-myc can bypass bcl-2 in vivo. Thus, the in vivo c-myc apoptotic pathway in
SBM mice occurs through a p53- and bcl-2-independent mechanism. We conclude that the
pathogenesis of PKD is c-myc specific and involves a critical imbalance between the opposing
processes of cell proliferation and apoptosis.
Polycystic kidney disease (PKD)1 is one of the most
prevalent and clinically important inherited renal diseases. Studies of genetic animal models have provided a
valuable in vivo system to investigate molecular and cellular
mechanisms of cystogenesis. We have generated the SBM
transgenic model which most closely resembles the human
autosomal dominant PKD renal phenotype (35). The SBM
transgene specifically targets c-myc to the renal tissue and
was fully penetrant for the cystic phenotype in all 18 transgenic lines produced. The fact that all 18 transgenic lines
developed PKD indicate that the site of transgene insertion
is not critical to the development of the renal phenotype.
The occurrence of spontaneous revertants in several different transgenic lines due to mutations in the transgene proves
that the intact transgene is required for the PKD phenotype
(34).
The course of PKD in the SBM mice evolves in a predictable manner with earliest detectable cyst formation in
late fetal development (E16.5), progressive multicystic renal
enlargement and inevitable development of renal failure in
young adulthood. Cysts are first detectable in glomeruli
and collecting tubules with later involvement of the more
proximal nephron (7). Tubular epithelial hyperplasia is an
integral feature of this model, often accompanied by microadenomas. Our studies into epithelial polarity have
shown that the cyst lining cells frequently display reversed
polarity similar to that of immature renal epithelium during
nephrogenesis (2).
Although the physiological roles of the c-myc protein
are poorly understood, c-myc is known to be involved in
cell proliferation, apoptosis, differentiation and neoplasia.
The critical role of the c-myc proto-oncogene in murine
development is underscored by the severe intrauterine
growth retardation of c-myc-null mice which fail to survive beyond E10.5 (8). Because these mice die (E9.5-E10.5) before renal metanephric development is initiated, these studies do not elucidate whether c-myc is essential for renal development. However, c-myc has been shown to be
particularly highly expressed in tissues of mesodermal origin such as the kidney (29, 32). During renal organogenesis, c-myc is highly expressed in noninduced metanephric
mesenchyme as well as in developing tubules of the mesonephros and metanephros (29). Upon metanephric induction and development, the high prevalence of cellular proliferation and apoptosis coincides with c-myc expression (5,
15). As fetal nephrogenesis progresses, there is continual
decrease of c-myc expression to undetectable levels at birth
(41). In contrast, in our SBM model, c-myc is not downregulated at birth but remains continually expressed in renal
tissue. Moreover, the renal epithelium has an immature
phenotype with respect to cellular hyperplasia and polarity,
findings which correlate with previous observations on the
reciprocal relationship between cell division and terminal differentiation.
Because of the compelling evidence that c-myc is a major mediator of cystogenesis, we set out to determine the
specificity of c-myc for this phenotype. We approached
this question by producing novel transgenic lines which
target two different genes, c-fos and TGF- Production of Transgenic Mice
The SBM fusion construct used to produce the SBM transgenic mouse lines has been described previously (35). In brief,
this construct consisted of the coding region of the c-myc proto-oncogene (exons 2, 3, and 3 The c-myc proto-oncogene in the SBM construct was substituted with the mouse c-fos gene in SBF mice. The The SBT construct was generated by substituting the human
TGF- The SBB was generated by substituting the human bcl-2
cDNA for the c-myc proto-oncogene in the SBM construct, as
described above for SBF. The bcl-2 sequence was contained
within a 758-bp (XbaI-Pst I) fragment located 58 bp upstream of
the translation initiation codon to +98 bp downstream of the
stop codon, linked to a 2,179-bp fragment of the human growth
hormone gene containing the last five exons and introns, followed by the polyadenylation site and 3 Transgene constructs were excised from plasmid sequences
isolated by agarose gel electrophoresis and purified by centrifugation on CsCl gradients. The constructs were microinjected into
the pronuclei of (C57BL/6J × CBA/J)F2 fertilized eggs. Positive
heterozygote transgenic SBM, SBF, SBT, and SBB mice were
identified by Southern Blot analysis of tail DNA using the entire
hybrid gene construct as a probe. The 32P-labeled probe was generated by nick translation of the entire plasmid.
Expression Analysis by In Situ Hybridization of
Adult Kidney
Renal tissues from SBM or SBF adults and nontransgenic littermate controls were fixed in paraformaldehyde and paraffin-embedded. Tissue sections were mounted on 3-aminopropyl triethoxy silane coated slides. SBM and control tissue sections were
hybridized with a uniformly 35S-labeled antisense probe produced
with the junction Analysis of Gene Expression
RNA Extraction.
Total RNA from mouse kidney was extracted by the acid guanidium-phenol-chloroform method as previously described (35). Final pellets were resuspended in sterile
DEPC treated water. Integrity of RNA was monitored on 0.8%
agarose formaldehyde gels.
Reverse Transcription PCR.
All RNA samples (3 µg) were simultaneously reverse transcribed into cDNA in BRL RT buffer
containing 0.5 mM each dNTP (Pharmacia LKB Nuclear, Gaithersburg, MD), 1.2 U/µl RNasin (Boehringer-Mannheim Corp.,
Indianapolis, IN), 200 U of M-MLV reverse transcriptase (GIBCO BRL, Gaithersburg, MD) and 5 µg of pd (N)6 random
primers (Pharmacia). Total reaction volume was 20 µl. Reverse
transcription PCR amplification was carried out at 37°C using
0.2-µl aliquots. All cDNAs to be quantified were amplified simultaneously in: PCR buffer (10 mM Tris, pH 8.3, 50 mM
KCL, 1.5 mM MgCl2) 0.2 mM each dNTP, 20 pmol of specific
primers (except for murine bcl-2, 40 pmol), 2 pmol of S16 primers (except for murine bcl-2, 1 pmol and bax, 5 pmol), and 0.5 units Taq polymerase (Perkin-Elmer Cetus Corp., Norwalk, CT)
in a total volume of 20 µl. Parallel control reactions were carried
out with water replacing DNA. Initial experiments were carried
out to ensure that conditions for PCR were within the linear
range of amplification.
, to the kidney.
Moreover, we sought to investigate the roles of c-myc-
driven proliferation and apoptosis and the relative contributions of potential regulators bcl-2, bax and p53 to decipher the
underlying in vivo cellular mechanisms and molecular pathways that mediate PKD.
flanking sequences) linked to the
-globin promoter contained within a 687-bp fragment and the
two 72-bp repeats of the SV40 enhancer.
-globin promoter (containing its own transcription initiation site "cap") and
the SV40 enhancer of the SBM regulatory elements were retained. Genomic c-fos DNA from +108 bp (located between the
cap and the translation initiation codon) (AccI) to +800 bp
downstream of the poly(A) site (BamHI) was juxtaposed downstream of these regulatory elements (gift of Dr. J. Deschamps,
Hubrecht Lab, Utrecht, The Netherlands). In addition, this transgenic construct contained a sea urchin marker of 130 bp (SalI)
(17) between the translation termination codon (+98 bp from
UAG) and the poly(A) site to differentiate the transgene from the
endogenous gene and to disrupt the specific destabilizing sequence within c-fos mRNA (27). All novel junctions created in
this construct were sequenced. Eight SBF transgenic lines were
established for this construct as described for SBM (35).
cDNA for the c-myc proto-oncogene in the SBM construct, as described above for SBF. TGF-
sequences were contained within a 925-bp BglII cDNA fragment linked to a 900-bp
fragment of the human growth hormone gene containing the 3
untranslated region, the polyadenylation site and 3
flanking sequence (gift of Dr. Glen Merlino, National Institutes of Health,
Bethesda, MD) (13). All new junctions in this hybrid construct
were also sequenced. Five SBT transgenic lines were established,
as described for SBM (35).
flanking sequence. Six
SBB transgenic lines were established.
-globin promoter/c-myc gene called "SBM
probe" (35). Similarly, the SBF, SBM, and control renal sections
were hybridized with a SBF antisense probe. This probe was produced with a BalI-HincII fragment containing the junction
-globin
promoter/c-fos from the SBF construct and uniformly 35S-labeled.
Sections were then washed and coated with Kodak NTBII emulsion for autoradiography. For controls, sense probe was utilized on mice positive and negative for the transgene; and antisense probe was used on renal tissue from transgene negative littermates. Photographs were taken using light and dark field optics.
-CTTCTGACACAACTGTGTTC-3
(forward; nt 42-61 including the cap site in the
-globin promoter)
whereas the reverse 5
-CACTAGAGACGGACAGATCT-3
(nt 1190-1209, exon 2 in fos) for SBF and 5
-AATGGGACACCACTGCTGCA-3
(nt 167-186, exon 2 in TGF-
) for SBT;
for SBB: 5
-TGTGGCCTTCTTTGAGTTCG-3
(nt 1899-1918, exon 2) and 5
TCACTTGTGGCTCAGATAGG-3
(nt
2159-2178, exon 3); for p53: 5
-CAGCCAAGTCTGTTATGTGC-3
(nt 456-475, exon 4) and 5
-ATGGTGGTATACTCAGAGCC-3
(nt 778-797, exon 7); for murine bcl-2: 5
-TGTGGCCTTCTTTGAGTTCG-3
(exon 1) and 5
-TCACTT-
GTGGCCCAGGTATG-3
(exon 2); for bax: 5
-GCGTCCACCAAGAAGCTGAG-3
(exon 3) and 5
-ACCACCCTGGTCTTGGATCC-3
(exon 5); for murine bad 5
-GAAGGGATGGAGGAGGAGCT-3
(nt 831-850) and 5
-GGAGCCTCCTTTGCCCAAGT-3
(nt 1051-1070). All reactions contained, as an internal control, a pair of primers to co-amplify the
mouse S16 ribosomal protein gene product: 5
-AGGAGCGATTTGCTGGTGTGGA-3
(nt 1451 -1472, exon 3) 5
-GCTACCAGGCCTTTGAGATGGA-3
(nt 1620-1641, exon 4) as
previously described (11). All RNA samples of SBT and SBB
were treated with RNase-free DNaseI before the reverse transcriptase reaction. Additional controls consisted in amplification of RNA before and after DNaseI treatment to ensure that any
contaminating DNA was eliminated.
Tunel Assay for Detection of Apoptosis in Tissue Sections
3-µm-thick paraffin sections of formalin fixed renal tissue from transgenic mice and age-matched controls were deparaffinized and hydrated in graded alcohols. Sections were incubated for 30 min at 37°C with a reaction buffer (1 M potassium cacodylate, 125 mM Tris-HCl, bovine serum albumin 1.25 mg/ml) (20:100), CoCl2 solution (1:100), TdT (0.4:100), and biotin 16-2 dUTP labeling mix (1:100) (containing 1 mM each dATP, dGTP, dCTP, and 0.65 mM dTTP, 0.35 mM biotin-16-dUTP in Tris-HCl) (Boehringer Mannheim). Endogenous peroxidase was blocked with 3%H2O2 for 30 min. Sections were incubated for 30 min in Avidin-Biotin Complex (Vector Labs., Inc., Burlingame, CA) followed by diaminobenzidine. Sections were counterstained with Periodic acid-Schiff. Apoptotic cells were quantitated by counting the number of stained tubular nuclei per mm2 of tissue.
Proliferation Index in Kidney Sections
Kidney from seven SBM transgenic adult mice and four control littermates were fixed in formalin and embedded in paraffin. 3-µm sections were deparaffinized and hydrated in graded alcohols. After blocking for endogenous peroxidase activity slides were microwaved for 25 min at 750 W. After PBS rinse and blocking with 10% goat serum, tissue sections were incubated overnight at 4°C with rabbit polyclonal antibody MIB-1 to Ki-67 (clone MM1) (Novacastra Labs, Newcastle Upon Tyne, UK) at 1:100 followed by biotinylated secondary antibody (Vector Labs., Inc.), followed by avidin/peroxidase complex (Vector Labs., Inc.) and DAB. Sections were counterstained with Mayer's hematoxylin (Sigma Chem. Co., St. Louis, MO). Proliferation index was calculated as number of MIB-1 positive cells per mm2 of tissue.
Cell Proliferation as One Mediator of SBM Renal Phenotype
Morphological studies in the SBM model demonstrated renal cysts are first detectable at E16.5, where they are manifested predominantly as glomerular cysts, followed by development of tubular cysts (35a). Both cyst number and size increased progressively with age, leading to end stage renal failure by age 3-6 mo (35). Cyst formation was associated with renal epithelial hyperplasia, occasionally leading to adenoma formation.
To determine the site and cellular localization of c-myc expression within the adult kidneys, we examined normal and cystic SBM kidneys by in situ hybridization. A strong expression of the c-myc transgene was specifically localized to the SBM renal cystic epithelium as well as focal noncystic tubules (Fig. 1 a), with undetectable signal in adult controls. This overexpression of c-myc in the renal epithelium correlated with the development of hyperplasia and abnormal polarity in many of the cystic tubules.
Because hyperplasia is a consistent feature of the SBM phenotype, the rate of epithelial proliferation was determined using antibody to murine MIB-1 (Ki-67), expressed in cycling cells. As shown in Table 1, the proliferation index was over 10-fold higher in SBM adult kidneys compared with controls. Proliferating cells were almost exclusively localized to the tubular epithelium with greater involvement of cystic tubules than non-cystic tubules (Fig. 1 b). MIB-1-positive cells were also frequently clustered in the tubular epithelial lining, suggesting an inductive or paracrine/juxtacrine signal.
|
Specificity of c-myc in the Induction of Renal Cystogenesis
To verify the specificity of the c-myc proto-oncogene in
cystogenesis, we investigated the potential of other proto-oncogenes/growth factors to induce a PKD phenotype. In
the first study, we substituted c-myc with c-fos sequences,
while retaining the SV40 and -globin regulatory elements
of the SBM construct, thereby generating a new construct,
SBF. c-fos was chosen because it is a well-characterized proto-oncogene with properties closely resembling those of
c-myc, including early response gene, cellular proliferation,
and the ability to promote epithelial proliferation in H2c-fos transgenic mice (27).
SBF transgenic mice carrying the SBF construct (Fig. 2)
were identified by Southern blot analysis of tail DNA.
Pathological examination of brain, lung, liver, spleen, and
kidney showed no gross or histological abnormalities. Specifically, no PKD phenotype or epithelial hyperplasia could
be identified in any of the 8 SBF transgenic lines. Unlike
the SBM mice which die of renal failure by 3-4 mo of age,
mice of the different SBF lines analyzed have a normal life
span of 2-3 yr.
Fig. 3 a shows RT-PCR analysis of the SBF transgene in the various organs (including kidney, liver, spleen, heart, lung, and brain). The highest levels of SBF transgene expression were obtained in kidney, where levels were demonstrated to be within the linear range (Fig. 3 b). Some expression was also occasionally detectable in spleen and lung, with little or undetectable expression in other organs (Fig. 3 a). This particular organ distribution of transgene expression closely resembles that described previously for SBM mice (35), and it is likely that the transgene is preferentially targeted to the kidney due to common regulatory elements with SBM. Furthermore, to determine more precisely the localization of the c-fos transgene in SBF kidneys, we have carried out in situ hybridization. Adult transgenic SBF kidneys demonstrated high expression of the transgene in tubular epithelial cells throughout the kidney, with particularly intense signal over the medullary collecting tubules (Fig. 4 a). This cellular localization is very similar to that observed for the c-myc transgene. No expression was detected in renal tissue of non transgenic controls (C57BL/6 × CBA)F1 (Fig. 4 b). Furthermore, c-fos expression was also investigated in the SBM mouse kidneys (Fig. 4 c); the absence of signal indicates that c-fos is not induced in the SBM c-myc-dependent cystogenic pathway.
In a further attempt to test the specificity of c-myc
within the SBM transgene, TGF- was selected as a substitute for c-myc because of its known mitogenic effect in fetal tissues where it is localized to the developing tubular epithelium during early nephrogenesis (36). This growth
factor has also been implicated in epithelial cell proliferation in the mammary glands of TGF-
transgenic mice (13,
19). Similarly to the SBF construct, the SBT construct was
produced as illustrated in Fig. 2. Five SBT transgenic lines
were generated and Fig. 5 show renal transgene expression
in a SBT line by RT-PCR analysis. However, the SBT transgenic lines, like the SBF lines, had no gross or microscopic abnormalities in any of the organs (lung, brain, liver,
kidney, spleen) analyzed.
Apoptosis as a Second Mediator in SBM Renal Phenotype
c-myc has been implicated in both cellular growth and proliferation as well as apoptosis (10). To determine the biological importance of these opposing cell processes for cystogenesis in SBM mice, we have complemented the epithelial proliferation studies with investigations into apoptosis and its molecular mechanisms.
Apoptosis in SBM Mice.In SBM adult mice apoptotic index determined by Tunel assay was approximately 100-fold higher than the negligeable apoptotic rate in nontransgenic littermate controls (Table 2). Apoptotic nuclei were often clustered in cystic epithelium suggesting a zonal effect that may be mediated by paracrine effects or local cell-cell/ cell-matrix interactions (Fig. 6).
|
Expression of bcl-2 and bax in SBM Renal Tissue.
It is well documented that Bcl-2, a major suppressor of apoptosis, is capable of abrogating c-myc induced apoptosis (3). Bcl-2 plays an important role in protecting different cell types from apoptotic death (26), and homozygous null bcl-2 mice develop renal cysts (23). Thus, we have compared bcl-2 expression levels in renal tissue of SBM transgenic mice with those of control littermates by RT-PCR. Comparable levels of bcl-2 expression were detected in SBM lines (SBM9 and 75) and controls (Fig. 7 a, top). The bcl-2 expression in SBM mice did not change significantly over a wide age range from birth to end stage renal disease (data not shown).
Because the bax/bcl-2 ratio was shown to be critical for cell survival and cell death, and because the promoter of the bax gene contains several binding sites for the myc family of transcription factors, we have investigated the levels of bax in SBM mice. RT-PCR analysis indicated that bax expression levels were similar in SBM mice and in control littermates (Fig. 7 a, bottom) and over a wide range of developmental stages (data not shown). Moreover, measurements of bad expression, another important proapoptotic member of bcl-2 family (40), have also shown no significant difference in expression levels between SBM kidney and controls from birth to adulthood (data not shown). Altogether these data indicate that some key members of the bcl-2 gene family do not play a significant role in the apoptotic pathway induced by c-myc in SBM mice.
Targeted Expression of Bcl-2 in SBM Kidney
To directly address whether overexpression of bcl-2 in
vivo can prevent c-myc-induced cystogenesis, we have
generated transgenic mice called SBB. This SBB construct
carries the complete human bcl-2 cDNA and is illustrated
in Fig. 2. Transgene expression was found in kidney and
spleen with low to undetectable levels in lung, brain and
liver (Fig. 7 b). These SBB transgenic lines have a normal
renal phenotype. The physiological importance of Bcl-2
within the c-myc-induced cystogenic pathway was then
tested by crossmating the 3 SBB lines showing highest
transgene expression (SBB 10, 11, and 20) with the SBM
75 line. Of 165 progenies produced, the renal phenotype
was analyzed for each of the four genotypes. Morphologic
studies on SBB/SBM
and SBB+/SBM
mice revealed
normal renal histology. The SBB+/SBM+ and SBB
/SBM+
mice had comparable morphologic features with typical
cystic phenotype indistinguishable from that of the pure
SBM line. Moreover, the clinical evolution of the renal
failure was similar in the double transgenic (SBB+/SBM+)
and SBM lines, with mean death due to renal failure at ~3
mo. Renal proliferation index in the double transgenic
SBB+/SBM+ mice was 89.2 ± 66.0, comparable to the
proliferation index of 99.4 ± 47.3 described for SBM
mice, (Table 1). It is of interest that the proliferation index
in the SBB+/SBM
mice is equivalent to that of negative
control littermates (10.4 ± 5.0 versus 8.7 ± 3.8). We then
investigated the implication of bcl-2 in the c-myc-dependent apoptotic pathway. Table 2 summarizes the renal apoptotic indices in the four genotypes generated from the
SBB × SBM crosses. Renal tissues from mice carrying the
SBM transgene had virtually identical apoptotic rates irrespective of the SBB genotype. Conversely, kidney tissues
from mice without the SBM transgene had identical apoptotic rates at least 30-fold lower than the SBM lines, irrespective of their SBB genotype. Thus it appears that overexpression of bcl-2 does not modify the SBM-dependent
apoptotic rate in vivo.
Expression of p53 in SBM Renal Tissue
p53 is a tumor suppressor gene that mediates c-myc-induced apoptosis (12, 38). Since c-myc is overexpressed in SBM kidney and renal tissues displayed a high apoptotic index, the level of p53 expression was investigated by RT-PCR analysis. Two transgenic mouse lines (SBM 9, SBM 75) at different stages of development (0.5 d, 10 d, 4 mo, end-stage) expressed approximately two- to threefold lower levels of p53 compared with negative age-matched littermates (Fig. 8 a), suggesting that p53 is not a major inducer of apoptosis in SBM. Proof that the expression analysis falls within the linear range is provided in Fig. 8 b.
To demonstrate that the apoptosis observed in SBM
mice is p53-independent, successive matings of SBM mice
were performed with p53-null mice. From several matings,
SBM/p53/
mice as well as SBM/p53+/
, SBM/p53+/+
and p53
/
littermates were obtained. The mean survival
of the SBM/p53
/
mice (n = 4) was 2.6 mo, virtually
identical to that of SBM/p53+/
mice (n = 16) and of
SBM/p53+/+ mice (n = 3). In adult SBM/p53
/
mice,
renal tubular cysts were numerous and large, resembling those of SBM mice (Fig. 8 c). The range of apoptotic indices in the SBM/p53
/
mice was within the range observed in SBM/p53+/+ and SBM/p53+/
(Table 3). Renal tissues of all three of these genotypes had greatly
increased apoptotic rates compared with the negligeable apoptosis seen in SBM negative littermates. By Tunel assay,
apoptosis was detected in renal cystic epithelial cells (Fig. 8
d), some of which had morphologically detectable nuclear
fragmentation (Fig. 8 e). These results indicate that apoptosis in this model is not abrogated by the absence of p53, but
occurs through a c-myc-dependent, p53-independent
pathway. These findings provide definitive evidence that
p53 is not required for cystogenesis in SBM/p53
/
mice
and support the inference from the quantitative RT-PCR
results that p53 does not play a major role in the induction
of apoptosis in SBM mice.
|
p53 has been shown to induce alterations in bcl-2 and
bax expression in some tissues (e.g., prostate epithelium,
thymus) but not in others (e.g., neurons) (20, 21). Because
this effect has not been documented in the kidney and because a common cell death pathway has been suggested for
p53 and bcl-2, we next analyzed the expression of bcl-2
and bax in the various SBM/p53 progenies. As shown in
Fig. 7 a, levels of bcl-2 and bax expression did not vary appreciably in SBM/p53/
mice compared with those in
SBM or even to control mice. These data indicate that in
the kidney bcl-2 and bax are not modulated by p53 or by
c-myc and imply the existence of other regulators of bcl-2
family members in kidney as reported for p53 in neurons (20).
To address the in vivo molecular and cellular processes induced by the c-myc protein, transgenic mice overexpressing this proto-oncogene in renal epithelial cells were generated. These SBM transgenic mice consistently produced a renal phenotype which closely mimics human PKD. Our results demonstrate that the properties of c-myc which induce PKD are specific since other proto-oncogenes with growth-related properties could not reproduce this phenotype. We have also shown that concomitant proliferation and apoptosis are specifically induced by c-myc and that both these processes are crucial determinants to the development of the renal phenotype. Using our c-myc transgenic model, we have determined that the in vivo role of c-myc in these cellular processes appears to be independent of the molecular pathways regulated by key members of the bcl-2 family. Moreover, we have established that in vivo c-myc-induced apoptosis is p53-independent.
To address the specificity of c-myc in the epithelial phenotype that underlies PKD, we investigated whether c-myc
could be substituted with another proto-oncogene (c-fos)
and a growth factor (TGF-) known to be operant in renal
development. Similar to the SBM transgene, these two
novel transgenes, SBF and SBT, were expressed in renal
tissue and specifically in tubular epithelium. In contrast to
the SBM, neither SBF nor SBT produced renal abnormalities. Hence, it appears that the high mitogenic potential of
TGF-
in epithelial cells is insufficient to cause a renal
PKD phenotype. Further, despite the implication of c-fos
in epithelial proliferation during renal organogenesis (37),
in acute nephrotoxic injury and in cystogenesis of cpk mice
(6), our results indicate that c-fos also does not play a major
role in cyst formation. Indeed, c-fos is not detected in adult
SBM kidneys and importantly, its overexpression in SBF
mice does not induce cystogenesis. This inability of the
SBF transgene to induce PKD cannot be explained by the
absence of c-jun, a heterodimeric partner required for c-fos
transcriptional activity, since c-jun is ubiquitously expressed (4). The renal SBM phenotype thus appears to be
independent of the c-fos signaling pathway. On the basis of
these results, we conclude that c-myc has specific renal cystogenic properties.
Targeting of c-myc to the kidney, the mammary gland and the hematopoietic cells has resulted in cellular hyperplasia in each of these tissues (1, 30, 35). In the SBM model, the consistent renal hyperplasia suggested a role for increased epithelial proliferation. Indeed, the SBM renal epithelium was highly proliferative (>10-fold), similar to our previous findings and those of others in human PKD (16, 22). In vitro cell culture studies have demonstrated that the levels of c-myc correlated with susceptibility to apoptosis, thereby suggesting a similar relationship in vivo in SBM renal epithelium. The rates of apoptosis in kidneys from our SBM mice were in fact, also highly elevated (10- 100-fold). This represents the first demonstration of concurrent c-myc-induced dysregulation of both proliferation and apoptosis in vivo. Interestingly, both these cellular processes frequently occur in a focal distribution suggestive of a paracrine signal or local tissue phenomena such as cell- cell or cell-matrix interactions. Furthermore, the occurrence of both these cellular mechanisms in the same tissue may explain the low frequency of adenomas in adult SBM mice. Indeed, the c-myc-driven hyperproliferation could theoretically promote a high frequency of cellular neoplasia and transformation, but this propensity is likely checked by the elevated apoptotic rate. In addition, our studies suggest that a similar temporal and spatial balance between c-myc- induced proliferation and apoptosis is critical to the development and progression of cyst formation and renal tissue remodeling. While in the human autosomal dominant polycystic kidney disease (ADPKD), we have demonstrated a consistent association between the upregulation of c-myc and the cellular dysregulation of proliferation and apoptosis (16), our studies in the SBM model provide strong evidence of causality.
Based on the specificity of c-myc for the cystic phenotype, we next sought to determine which molecular pathways underlie the proliferative and apoptotic cellular processes. It is likely that critical factors govern the cell's
differential susceptibility to these opposing c-myc-regulated functions. Two of these factors, p53 and Bcl-2, previously shown to be involved in these complex cellular pathways have been investigated. p53 is a well-recognized factor which mediates c-myc-induced apoptosis. c-myc
can induce apoptosis by causing an approximately three-fold increase in p53 mRNA levels followed by an increase
in protein levels (12). Since our data show an approximately twofold decrease in p53 expression, this suggests
that p53 does not play a major role in the SBM apoptotic pathway. The apoptosis observed in SBM mice was confirmed to be p53-independent by studies in SBM/p53/
and SBM/p53+/
mice, which displayed similar apoptotic
index and renal pathology to the SBM mice. These results
implicate the existence of an in vivo c-myc induced apoptotic pathway that is independent of p53. In agreement
with our results, in vivo studies by others have reported the
existence of a p53-independent pathway in different tissues
which express two other oncoproteins (SV40 T-antigen
and HPV-16E7) (18, 25) but the pathway for c-myc in
vivo had not been investigated. Furthermore, the observation in our model that bax expression levels do not appear
modulated in this c-myc-dependent p53-independent
pathway is consistent with the proposed model that c-myc
can cause bax induction only through p53 activation in immortalized epithelial cells (BRK) (28). A p53-independent apoptotic pathway(s) had also been inferred from our studies on human ADPKD, since no induction of p53 or bax
was associated with the increased c-myc expression and the
dysregulation of apoptosis and proliferation in both fetal
and end-stage polycystic kidneys (16). Thus the demonstration of a p53-independent apoptotic pathway in the c-myc-
induced PKD mouse model not only corroborates our human data but also validates the relevance of the SBM model for molecular studies of human ADPKD.
Indirectly, the existence in vivo of a p53-independent apoptotic mechanism in renal epithelium is also supported by the observation that p53-null mice display normal kidney development and homeostasis (9), even though renal organogenesis requires high levels of apoptosis (15). In fact, renal organogenesis is dependent on concomitant cellular apoptosis and proliferation associated with high levels of c-myc expression; on completion of kidney ontogeny, these cellular processes are virtually abrogated and c-myc expression is turned off. In our PKD model, it is likely that the c-myc induced persistence of apoptosis independent of p53, together with the epithelial proliferation and incomplete epithelial differentiation (2) results from a failure to switch out of a developmental program. Indeed, cystogenesis becomes morphologically evident in utero when renal organogenesis is almost completed.
Various studies have shown that the apoptotic pathway
induced by c-myc can be abrogated in hematopoietic and
fibroblast cells (3, 38) by overexpression of bcl-2 and that a
decrease in the Bcl-2/Bax ratio is believed to determine
cell death (24). In SBM mice, although the apoptotic index
was elevated in renal tissue, bcl-2 expression levels were
not significantly decreased compared with controls. Moreover bax levels were not appreciably increased, suggesting
that the Bcl-2/Bax ratio is not an important determinant of
the c-myc-dependent cystic phenotype. Confirmation that
Bcl-2 does not play a major role in SBM cystogenesis was obtained by its overexpression in the many double bcl-2/
c-myc transgenic mouse lines. Strikingly the overexpression of bcl-2 in SBM renal epithelium could not block the
cell death pathway and rescue the cystic phenotype, indicating that the cellular effects of c-myc are Bcl-2 independent in this model. Furthermore, the double transgenic
mice did not have a higher incidence of tumor formation,
in contrast to the previous transgenic mice expressing c-myc
and bcl-2 in lymphoid cells (33). These findings suggest first that the c-myc dependent apoptotic pathway can bypass Bcl-2 in vivo and likely involves other regulatory
factors that are not inhibited by Bcl-2. Second, susceptibility to tumor formation mediated by c-myc and bcl-2 expression is likely to be a function of specific cell types. The
inability of the double bcl-2/c-myc transgenic mice to rescue the SBM phenotype is in apparent contradiction to the
cystic phenotype of the bcl-2 knockout mouse (23). However, the bcl-2/
mouse model more closely resembles
cystic hypoplasia than PKD, since tubular cysts are produced without renal enlargement (31). Our results are congruent with the bax knock-out mouse, which has no renal
abnormalities (14). Altogether these data suggest that apoptosis can be modulated either by bcl-2 overexpression, as
described for several cell lines (3, 28) or can proceed via a
bcl-2-independent pathway as demonstrated in vivo by our mouse model of PKD.
The molecular and cellular mechanisms of cystogenesis induced by c-myc in SBM mice closely resemble those previously reported for human ADPKD. Indeed, we have shown that c-myc is consistently highly overexpressed in human ADPKD (16). In both murine and human PKD, there is markedly elevated renal epithelial proliferation (16, 22) and apoptosis (16, 39) of approximately similar magnitude (10-100-fold) compared with normal kidneys. These similarities also extend to the renal expression levels of pro- and anti-apoptotic genes. In ADPKD, bax expression remains virtually unaltered and p53 varies from normal to slightly decreased by no more than two- to threefold, remarkably similar to our results in SBM mice. While bcl-2 expression levels appear unchanged in SBM mice, these are increased in human ADPKD in the face of elevated apoptotic rates, indicating that apoptosis in human ADPKD may also bypass Bcl-2. Together these findings in human ADPKD and the SBM model strongly support the existence of a common c-myc induced Bcl-2- and p53-independent apoptotic pathway in the mediation of renal cystogenesis.
In conclusion our data indicate that the PKD phenotype observed in the SBM mouse model is dependent on specific properties of the c-myc transgene. Our results on the c-myc induced maintenance of concomitant proliferation and apoptosis in the SBM mouse, also suggested in human ADPKD (16), are highly reminiscent of the normal processes operant in the renal developmental program. Importantly, these concurrent and opposing cellular mechanisms are likely essential for progressive growth and dynamic remodeling of renal cysts. The cellular apoptotic processes mediated by c-myc appear independent of bcl-2-regulated pathways. Moreover we have demonstrated for the first time the existence in vivo of a renal c-myc-dependent apoptotic pathway that is p53-independent.
Address correspondence to Marie Trudel, Ph.D., Institut de Recherches Cliniques de Montréal, 110, avenue des Pins Ouest, Montréal, Québec, Canada H2W 1R7. Phone: (514) 987-5712; FAX: (514) 987-5585.
Received for publication 20 June 1997 and in revised form 22 September 1997.
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