Essential role of the CUL4B ubiquitin ligase in extra-embryonic tissue development during mouse embryogenesis

Mutations of the CUL4B ubiquitin ligase gene are causally linked to syndromic X-linked mental retardation (XLMR). However, the pathogenic role of CUL4B mutations in neuronal and developmental defects is not understood. We have generated mice with targeted disruption of Cul4b, and observed embryonic lethality with pronounced growth inhibition and increased apoptosis in extra-embryonic tissues. Cul4b, but not its paralog Cul4a, is expressed at high levels in extra-embryonic tissues post implantation. Silencing of CUL4B expression in an extra-embryonic cell line resulted in the robust accumulation of the CUL4 substrate p21^Cip1/WAF and G2/M cell cycle arrest, which could be partially rescued by silencing of p21^Cip1/WAF. Epiblast-specific deletion of Cul4b prevented embryonic lethality and gave rise to viable Cul4b null mice. Therefore, while dispensable in the embryo proper, Cul4b performs an essential developmental role in the extra-embryonic tissues. Our study offers a strategy to generate viable Cul4b-deficient mice to model the potential neuronal and behavioral deficiencies of human CUL4B XLMR patients.     

CUL4B ubiquitin ligase in mouse development: A model for human X-linked mental retardation syndrome?

CUL4B, a member of the cullin-RING ubiquitin ligase family, is frequently mutated in X-linked mental retardation (XLMR) patients. The study by Liu et al. showed that Cul4b plays an essential developmental role in the extra-embryonic tissues, while it is dispensable in the embryo proper during mouse embryogenesis. Viable Cul4b-null mice provide the first animal model to study neuronal and behavioral deficiencies seen in human CUL4B XLMR patients.CUL4 is a member of the cullin-RING ubiquitin ligase family, the largest E3 ligase family, which appears to account for ∼20% of total protein degradation by the ubiquitin-proteasome system^1,2,3. CUL4 is conserved during evolution from yeast to human. In yeast, CUL4 encodes a single gene, but mammalian cells express two closely related paralogs, CUL4A and CUL4B with about 82% sequence identity. CUL4A and CUL4B assemble structurally similar E3 complexes through binding to an adaptor protein (DDB1) and a substrate receptor protein (DCAF) at the N-terminus, and a RING protein RBX1 at the C-terminus (Figure 1), and share functional redundancy in targeting substrates such as p21 and Cdt1 for ubiquitination and degradation^1,2. The Cul4a-null mice are viable and display no abnormal development and growth phenotypes, likely due to functional compensation from Cul4b^4,5. The only phenotype associated with Cul4a abrogation is the reproductive defects seen with male but not female mice, resulting from differential non-overlapping expression patterns of the two Cul4 genes during male meiosis⁶. On the other hand, germline deletion of Cul4b resulted in embryonic lethality around E9.5⁷, indicating a unique function of Cul4b that cannot be compensated by Cul4a during embryogenesis.Open in a separate windowFigure 1Differential expression of Cul4a and Cul4b in the embryo proper and extra embryonic tissues determines their fate. Before implantation, both Cul4a and Cul4b are expressed in the blastocyst. Following implantation, Cul4a is expressed in the embryo proper, but not in extra-embryonic tissues. Upon Cul4b deletion, p21 accumulates in extra-embryonic tissues to induce G2/M arrest and eventually embryonic death due to degeneration of extra-embryonic tissues. Expression of Cul4a in embryo prevents p21 accumulation and subsequent embryonic death.Mental retardation (MR) affects approximately 1%-3% of the population and is about 30% more common in males than in females⁸, suggesting a causal relationship with gene mutations on the X chromosome. To date, mutations in about 100 genes have been identified in X-linked MR (XLMR), much more than those found on autosomes⁹. In 2007, two independent groups reported that mutations of CUL4B (Xq24) ubiquitin ligase gene are associated with XLMR^10,11. CUL4B-deficient patients display a syndrome of delayed puberty, moderate short stature, hypogonadism, relative macrocephaly, central obesity, fine intention tremor, brachydactyly, and large tongue^10,11. Similarly, the neuronal and developmental deficiencies found in XLMR patients with CUL4B mutations are not compensated by CUL4A. The studies of the molecular pathogenesis of human XLMR are lagging partly due to the lack of an animal model for the disease.In the most recent study published in Cell Research, Zhou and coworkers¹² attempted to generate conditional Cul4b knockout mice with targeted deletion of Cul4b at exons 4 and 5, giving rise to a non-functional Cul4b fragment lacking both the DDB1-binding domain and the cullin homology domain for RBX1 recruitment. The chicken-actin (CAG)-Cre was used, which drives Cre-mediated recombination at the early zygote stage, leading to Cul4b deletion in both the embryo proper and extra-embryonic tissues. Like human CUL4B, the mouse Cul4b is also located on the X-chromosome. Intercrossing of male CAG-Cre with female Cul4b^fl/+ revealed that hemizygous deletion of Cul4b causes embryonic lethality. No embryos with the genotype of Cul4b^−/y survived beyond E9.5. Interestingly, the heterozygous Cul4b^+/− embryos also die in the uterus before E13.5, suggesting that the paternal X chromosome undergoes imprinted inactivation with only trace amount, if any, of Cul4b expression remaining in extra-embryonic tissues. Detailed analysis of dissected embryos revealed that dying Cul4b^+/− embryos (E12.5) lack blood supply from the yolk sacs, whereas the Cul4b^−/y embryos (E8.5) showed remarkable reduction in proliferation with growth arrest at G2/M and enhanced apoptosis. The authors went on and investigated why Cul4a failed to compensate the loss of Cul4b, and found a dynamic expression pattern, differing between two forms, during early embryonic development. Prior to implantation, both Cul4 proteins are detectable in the blastocysts. Shortly after implantation, while both forms are expressed in the embryo proper, only Cul4b is expressed in the extra-embryonic tissues. Thus, upon Cul4b deletion, extra-embryonic tissues without Cul4a compensation degenerate, eventually leading to embryonic death. Consistently, when the authors deleted Cul4b in the epiblast using the Sox2-Cre (targeted Cul4b deletion in embryos proper only), viable Cul4b-null mice are produced likely due to Cul4a compensation. Thus, Cul4b is essential for the development of extra-embryonic tissues, but is dispensable for embryogenesis itself.To study the potential underlying mechanism(s) of embryonic lethality upon Cul4b deletion in extra-embryonic tissues, the authors used an extra-embryonic cell line (XEN). Cul4b knockdown induced a remarkable cell cycle arrest at the G2/M phase, consistent with observation made in Cul4b-null embryos, and robust accumulation of p21, a universal inhibitor of cyclin dependent kinase and a known substrate of Cul4¹. To determine whether accumulated p21 is responsible for the G2/M arrest, the authors simultaneously knocked down both Cul4b and p21 in XEN cells and observed a partial abrogation of growth arrest, suggesting that p21 plays a causal role, at least in part. Unfortunately, due to unavailability of anti-mouse p21 antibody specific for immunohistochemical staining, the authors were not able to show if p21 is indeed accumulated in extra-embryonic tissues upon Cul4b deletion. However, whether p21 indeed plays a causal role in embryonic death upon Cul4b deletion can be unequivocally determined by a rescuing experiment in which simultaneous deletion of p21 should abrogate or at least delay embryonic lethality, if it is causal. Nevertheless, the study by Zhou''s group can be summarized as follows. Before implantation, both Cul4a and Cul4b ubiquitin ligases are expressed in the blastocyst (inner cell mass and trophoblast cells). Following embryo implantation, while Cul4b is expressed in both the embryo proper and extra embryonic tissues, Cul4a is only expressed in the embryo proper. The CAG-Cre-driven Cul4b deletion (in both the embryo proper and extra-embryonic tissues) causes significant p21 accumulation in Cul4a non-expressing extra-embryonic tissues, resulting in G2/M arrest, followed by embryonic death due to degeneration of extra-embryonic tissues. On the embryo side, Cul4b deletion has no detrimental consequence, benefiting from the compensatory effect of Cul4a for p21 targeting. The same holds true when Cul4b is deleted driven by embryonic specific Sox2-Cre (Figure 1).It is noteworthy that the studies by Zhou''s group revealed two distinct differences between Cul4b KO mice and CUL4B-associated XLMR patients. First, Cul4b deletion at the zygote stage causes embryonic lethality, whereas XLMR patients with CUL4B mutations live to adulthood. Second, the Cul4b-null allele cannot be transmitted from the mother to the offspring, whereas human XLMR patients inherit X-linked CUL4B mutations from their mothers. Nevertheless, viable Cul4b-null mice (upon epiblast ablation by Sox2-Cre) provide the first mouse model for mechanistic study of human XLMR diseases associated with CUL4B mutations in the following three aspects:First, as noted earlier, human CUL4B XLMR patients have multiple neuronal and developmental defects. An obvious follow-up study will be to use this mouse model for neurological and behavioral analyses to determine whether Cul4b-null mice indeed present some of human XLMR symptoms.Second, this model can also be used to validate whether accumulation of Cul4b substrates during various stages of brain development indeed plays a pathogenic role and contributes to the clinical symptoms of XLMR patients. For instance, WDR5, a recently identified gene affecting general cognitive ability¹³, was found to be a novel nuclear substrate of CUL4B, but not CUL4A¹⁴. Investigation into whether WDR5 is abnormally accumulated upon Cul4b deletion in vivo would rule in or rule out its potential association with human XLMR, although it was not the case in this study using an extra-embryonic cell line in vitro.Third, the viability of Cul4b-null mice upon epiblast-specific deletion provides opportunities to study neuronal specific ablation of Cul4b in association with the pathogenesis of CUL4B-associated XLMR. For example, Cul4b is expressed at high levels in the hippocampus and cerebrum of mouse brains; both regions are affected in MR patients¹⁵. Thus, the use of Cre mouse lines that target the deletion of Cul4b in the entire brain, selected brain areas, or specific neuronal cells in both spatial and temporal manners¹⁶ would reveal potential contributions of particular regions and cell types to the development and symptoms of CUL4B-associated XLMR.A number of questions that warrant future investigation remain unanswered. First, in addition to p21, what are the other Cul4B substrates, which also contribute to degeneration of extra-embryonic tissues upon Cul4b deletion, since simultaneous deletion of p21 only partially rescues the growth defects? Second, besides the difference in tissue/cell specific expression seen in this study, are Cul4a and Cul4b targeting a unique set of substrates non-redundantly, thus differentiating their physiological functions? A related question will be why CUL4A cannot compensate for the loss of CUL4B in CUL4B-associated XLMR patients? Third, what is the pathogenic mechanism for CUL4B-associated XLMR? Is it mainly due to pathological accumulation of many CUL4B substrates? Answers to these questions may offer insights into potential therapeutic strategies for the treatment of CUL4B-associated XLMR patients.In summary, the findings reported by Zhou''s group provide the first convincing evidence that demonstrates an essential role of Cul4b in the development of extra-embryonic tissues during mouse embryogenesis. The viable Cul4b conditional knockout mice, generated in this study, may serve as the first mouse model for future mechanistic studies of neuronal and behavioral deficiencies of human XLMR associated with CUL4B mutations. We look forward to more exciting discoveries of how Cul4b deficiency leads to the development of XLMR in years to come.     

Requirement of Bmp8b for the generation of primordial germ cells in the mouse

In the mouse embryo, the generation of primordial germ cells (PGCs) from the epiblast requires a bone morphogenetic protein-4 (BMP4) signal from the adjacent extraembryonic ectoderm. In this study, we report that Bmp8b, a member of the Gbb-60A class of the BMP superfamily, is expressed in the extraembryonic ectoderm in pregastrula and gastrula stage mouse embryos and is required for PGC generation. A mutation in Bmp8b on a mixed genetic background results in the absence of PGCs in 43% null mutant embryos and severe reduction in PGC number in the remainder. The heterozygotes are unaffected. On a largely C57BL/6 background, Bmp8b null mutants completely lack PGCs, and Bmp8b heterozygotes have a reduced number of PGCs. In addition, Bmp8b homozygous null embryos on both genetic backgrounds have a short allantois, and this organ is missing in some more severe mutants. Since Bmp4 heterozygote embryos have reduced numbers of PGCs, we used a genetic approach to generate double-mutant embryos to study interactions of Bmp8b and Bmp4. Embryos that are double heterozygotes for the Bmp8b and Bmp4 mutations have similar defects in PGC number as Bmp4 heterozygotes, indicating that the effects of the two BMPs are not additive. These findings suggest that BMP4 and BMP8B function as heterodimers and homodimers in PGC specification in the mouse.     

A role for Saccharomyces cerevisiae Cul8 ubiquitin ligase in proper anaphase progression

We have undertaken a study of the yeast cullin family members Cul3 and Cul8, as little is known about their biochemical and physiological functions. We demonstrate that these cullins are associated in vivo with ubiquitin ligase activity. We show that Cul3 and Cul8 are functionally distinct from Cdc53 and do not interact with ySkp1, suggesting that they target substrates by Skp1- and possibly F-box protein-independent mechanisms. Whereas null mutants of CUL3 appear normal, yeast cells lacking CUL8 have a slower growth rate and are delayed in their progress through anaphase. The anaphase delay phenotype can be complemented by ectopic expression of Cul8 but not by any other yeast or human cullins, nor by a cul8 mutant deficient in binding to RING finger protein Roc1. Deletion of the RAD9 gene suppressed the anaphase delay phenotype of cul8delta, suggesting that loss of Cul8 function may compromise genomic integrity. These results indicate that in addition to the anaphase promoting complex, mitotic progression may involve another E3 ubiquitin ligase mediated by Cul8 protein.     

X-linked intellectual disability gene CUL4B targets Jab1/CSN5 for degradation and regulates bone morphogenetic protein signaling

Cullin 4B (CUL4B) is a scaffold protein involved in the assembly of cullin-RING ubiquitin ligase (E3) complexes. Contemporary reports have identified multiple mutations of CUL4B gene as being causally associated with X-linked intellectual disability (XLID). Identifying the specific protein substrates will help to better understand the physiological functions of CUL4B. The current study identified Jun activation domain-binding protein (Jab1/CSN5) in the COP9 signalosome (CSN) complex as a novel proteolytic target for the CUL4B ubiquitin ligase complex. The impaired degradation of Jab1 was observed in cells after RNAi-mediated CUL4B depletion. Integrity of DDB1-CUL4B-ROC1 was further demonstrated to be indispensable for the degradation of Jab1. In addition, the degradation of Jab1 is independent of CUL4A, a cullin family member closely related to CUL4B. In vitro and in vivo ubiquitination assays revealed that CUL4B promoted the polyubiquitination of Jab1. Interestingly, CUL4B-silenced cells were shown to exhibit abnormal upregulation of bone morphogenetic protein (BMP) signaling. Furthermore, in vivo studies of embryonic fibroblasts in Cul4b-deficient mice demonstrated Jab1 accumulation and increased activation of the BMP signaling pathway. Together, the current findings demonstrate the CUL4B E3 ubiquitin ligase plays a key role in targeting Jab1 for degradation, potentially revealing a previously undocumented mechanism for regulation of the BMP signaling pathway involved with the CUL4B-based E3 complex. This observation may provide novel insights into the molecular mechanisms underlying CUL4B-associated XLID pathogenesis.     

Cul4A is essential for spermatogenesis and male fertility

The mammalian Cul4 genes, Cul4A and Cul4B, encode the scaffold components of the cullin-based E3 ubiquitin ligases. The two Cul4 genes are functionally redundant. Recent study indicated that mice expressing a truncated CUL4A that fails to interact with its functional partner ROC1 exhibit no developmental phenotype. We generated a Cul4A−/− strain lacking exons 4–8 that does not express any detectable truncated protein. In this strain, the male mice are infertile and exhibit severe deficiencies in spermatogenesis. The primary spermatocytes are deficient in progression through late prophase I, a time point when expression of the X-linked Cul4B gene is silenced due to meiotic sex chromosome inactivation. Testes of the Cul4A−/− mice exhibit extensive apoptosis. Interestingly, the pachytene spermatocytes exhibit persistent double stranded breaks, suggesting a deficiency in homologous recombination. Also, we find that CUL4A localizes to the double stranded breaks generated in pre-pachytene spermatocytes. The observations identify a novel function of CUL4A in meiotic recombination and demonstrate an essential role of CUL4A in spermatogenesis.     

An adenosine triphosphatase of the sucrose nonfermenting 2 family, androgen receptor-interacting protein 4, is essential for mouse embryonic development and cell proliferation

An adenosine triphosphatase of the sucrose nonfermenting 2 protein family, androgen receptor-interacting protein 4 (ARIP4), modulates androgen receptor activity. To elucidate receptor-dependent and -independent functions of ARIP4, we have analyzed Arip4 gene-targeted mice. Heterozygous Arip4 mutants were normal. Arip4 is expressed mainly in the neural tube and limb buds during early embryonic development. Arip4-/- embryos were abnormal already at embryonic d 9.5 (E9.5) and died by E11.5. At E9.5 and E10.5, almost all major tissues of Arip4-null embryos were proportionally smaller than those of wild-type embryos, and the neural tube was shrunk in some Arip4-/- embryos. Dramatically reduced cell proliferation and increased apoptosis were observed in E9.5 and E10.5 Arip4-null embryos. Mouse embryonic fibroblasts (MEFs) isolated from Arip4-/- embryos ceased to grow after two to three passages and exhibited increased apoptosis and decreased DNA synthesis compared with wild-type MEFs. Comparison of gene expression profiles of Arip4-/- and wild-type MEFs at E9.5 revealed that putative ARIP4 target genes are involved in cell growth and proliferation, apoptosis, cell death, DNA replication and repair, and development. Collectively, ARIP4 plays an essential role in mouse embryonic development and cell proliferation, and it appears to coordinate multiple essential biological processes, possibly through a complex chromatin remodeling system.     

The CUL7 E3 ubiquitin ligase targets insulin receptor substrate 1 for ubiquitin-dependent degradation

Recent genetic studies have documented a pivotal growth-regulatory role played by the Cullin 7 (CUL7) E3 ubiquitin ligase complex containing the Fbw8-substrate-targeting subunit, Skp1, and the ROC1 RING finger protein. In this report, we identified insulin receptor substrate 1 (IRS-1), a critical mediator of the insulin/insulin-like growth factor 1 signaling, as a proteolytic target of the CUL7 E3 ligase in a manner that depends on mammalian target of rapamycin and the p70 S6 kinase activities. Interestingly, while embryonic fibroblasts of Cul7-/- mice were found to accumulate IRS-1 and exhibit increased activation of IRS-1's downstream Akt and MEK/ERK pathways, these null cells grew poorly and displayed phenotypes reminiscent of those associated with oncogene-induced senescence. Taken together, our findings demonstrate a key role for the CUL7 E3 in targeting IRS-1 for degradation, a process that may contribute to the regulation of cellular senescence.     

Essential function of PTP-PEST during mouse embryonic vascularization, mesenchyme formation, neurogenesis and early liver development

PTP (protein-tyrosine phosphatase)-PEST is a ubiquitously expressed cellular regulator of integrin signalling. It has been shown to bind several molecules such as Shc, paxillin and Grb2, that are involved downstream of FAK (focal adhesion kinase) pathway. Through its specific association to p130cas and further dephosphorylation, PTP-PEST plays a critical role in cell-matrix interactions, which are essential during embryogenesis. We report here that ablation of the gene leads to early embryonic lethality, correlating well with the high expression of the protein during embryonic development. We observed an increased level of tyrosine phosphorylation of p130cas protein in E9.5 PTP-PEST(-/-) embryos, a first evidence of biochemical defect leading to abnormal growth and development. Analysis of null mutant embryos revealed that they reach gastrulation, initiate yolk sac formation, but fail to progress through normal subsequent developmental events. E9.5-10.5 PTP-PEST(-/-) embryos had morphological abnormalities such as defective embryo turning, improper somitogenesis and vasculogenesis, impaired liver development, accompanied by degeneration in both neuroepithelium and somatic epithelia. Moreover, in embryos surviving until E10.5, the caudal region was truncated, with severe mesenchyme deficiency and no successful liver formation. Defects in embryonic mesenchyme as well as subsequent failure of proper vascularization, liver development and somatogenesis, seemed likely to induce lethality at this stage of development, and these results confirm that PTP-PEST plays an essential function in early embryogenesis.     

Targeted ubiquitination of CDT1 by the DDB1-CUL4A-ROC1 ligase in response to DNA damage

Cullins assemble a potentially large number of ubiquitin ligases by binding to the RING protein ROC1 to catalyse polyubiquitination, as well as binding to various specificity factors to recruit substrates. The Cul4A gene is amplified in human breast and liver cancers, and loss-of-function of Cul4 results in the accumulation of the replication licensing factor CDT1 in Caenorhabditis elegans embryos and ultraviolet (UV)-irradiated human cells. Here, we report that human UV-damaged DNA-binding protein DDB1 associates stoichiometrically with CUL4A in vivo, and binds to an amino-terminal region in CUL4A in a manner analogous to SKP1, SOCS and BTB binding to CUL1, CUL2 and CUL3, respectively. As with SKP1-CUL1, the DDB1-CUL4A association is negatively regulated by the cullin-associated and neddylation-dissociated protein, CAND1. Recombinant DDB1 and CDT1 bind directly to each other in vitro, and ectopically expressed DDB1 bridges CDT1 to CUL4A in vivo. Silencing DDB1 prevented UV-induced rapid CDT1 degradation in vivo and CUL4A-mediated CDT1 ubiquitination in vitro. We suggest that DDB1 targets CDT1 for ubiquitination by a CUL4A-dependent ubiquitin ligase, CDL4A(DDB1), in response to UV irradiation.     

Cullin4B/E3-ubiquitin ligase negatively regulates beta-catenin

Beta-catenin is the key transducer of Wingless-type MMTV integration site family member (Wnt) signalling, upregulation of which is the cause of cancer of the colon and other tissues. In the absence of Wnt signals, beta-catenin is targeted to ubiquitin-proteasome-mediated degradation. Here we present the functional characterization of E3-ubiquitin ligase encoded by cul4B. RNAi-mediated knock-down of Cul4B in a mouse cell line C3H T10 (1/2) results in an increase in beta-catenin levels. Loss-of-function mutation in Drosophila cul4 also shows increased beta-catenin/Armadillo levels in developing embryos and displays a characteristic naked-cuticle phenotype. Immunoprecipitation experiments suggest that Cul4B and beta-catenin are part of a signal complex in Drosophila, mouse and human. These preliminary results suggest a conserved role for Cul4B in the regulation of beta-catenin levels.     

Expression of Notch signaling pathway genes in mouse embryos lacking beta4galactosyltransferase-1

A requirement for beta4galactosyltransferase-1 (beta4GalT-1) activity in the modulation of Notch signaling by the glycosyltransferase Fringe was previously identified in a mammalian co-culture assay. Notch signaling is necessary for the formation of somites in mammals. We therefore investigated the expression of eleven Notch pathway and somitogenic genes in E9.5 mouse embryos lacking beta4GalT-1. Four of these genes were altered in expression pattern or expression level. The Notch target genes Hes5 and Mesp2 were affected to some degree in all mutant embryos. The Notch ligand genes Dll1 and Dll3 were reduced or altered in expression in a significant proportion of mutants. While there were no differences in the number or morphology of somites in E9.5 B4galt1 null embryos, the number of lumbar vertebrae in mutant embryos differed from control littermates (P < or = 0.01). The subtlety of the in vivo phenotype may be due to redundancy since several B4galt genes related to B4galt1 are expressed during embryogenesis.     

Characterization of Nuclear Localization Signal in the N Terminus of CUL4B and Its Essential Role in Cyclin E Degradation and Cell Cycle Progression

CUL4A and CUL4B, which are derived from the same ancestor, CUL4, encode scaffold proteins that organize cullin-RING ubiquitin ligase (E3) complexes. Recent genetic studies have shown that germ line mutation in CUL4B can cause mental retardation, short stature, and other abnormalities in humans. CUL4A was observed to be overexpressed in breast and hepatocellular cancers, although no germ line mutation in human CUL4A has been reported. Although CUL4A has been known to be involved in a number of cellular processes, including DNA repair and cell cycle regulation, little is known about whether CUL4B has similar functions. In this report, we tested the functional importance of CUL4B in cell proliferation and characterized the nuclear localization signal (NLS) that is essential for its function. We found that RNA interference silencing of CUL4B led to an inhibition of cell proliferation and a prolonged S phase, due to the overaccumulation of cyclin E, a substrate targeted by CUL4B for ubiquitination. We showed that, unlike CUL4A and other cullins that carry their NLS in their C termini, NLS in CUL4B is located in its N terminus, between amino acid 37 and 40, KKRK. This NLS could bind to importin α1, α3, and α5. NLS-deleted CUL4B was distributed in cytoplasm and failed to promote cell proliferation. Therefore, the nuclear localization of CUL4B mediated by NLS is critical for its normal function in cell proliferation.     

Dimerization of CUL7 and PARC is not required for all CUL7 functions and mouse development

CUL7, a recently identified member of the cullin family of E3 ubiquitin ligases, forms a unique SCF-like complex and is required for mouse embryonic development. To further investigate CUL7 function, we sought to identify CUL7 binding proteins. The p53-associated, parkin-like cytoplasmic protein (PARC), a homolog of CUL7, was identified as a CUL7-interacting protein by mass spectrometry. The heterodimerization of PARC and CUL7, as well as homodimerization of PARC and CUL7, was confirmed in vivo. To determine the biological role of PARC by itself and in conjunction with CUL7, a targeted deletion of Parc was created in the mouse. In contrast to the neonatal lethality of the Cul7 knockout mice, Parc knockout mice were born at the expected Mendelian ratios and exhibited no apparent phenotype. Additionally, Parc deletion did not appear to affect the stability or function of p53. These results suggest that PARC and CUL7 form an endogenous complex and that PARC and CUL7 functions are at least partially nonoverlapping. In addition, although PARC and p53 form a complex, the absence of effect of Parc deletion on p53 stability, localization, and function suggests that p53 binding to PARC may serve to control PARC function.