N-terminal methionine removal and methionine metabolism in Saccharomyces cerevisiae

Methionine aminopeptidase (MetAP) catalyzes removal of the initiator methionine from nascent polypeptides. In eukaryotes, there are two forms of MetAP, type 1 and type 2, whose combined activities are essential, but whose relative intracellular roles are unclear. Methionine metabolism is an important aspect of cellular physiology, involved in oxidative stress, methylation, and cell cycle. Due to the potential of MetAP activity to provide a methionine salvage pathway, we evaluated the relationship between methionine metabolism and MetAP activity in Saccharomyces cerevisiae. We provide the first demonstration that yeast MetAP1 plays a significant role in methionine metabolism, namely, preventing premature activation of MET genes through MetAP function in methionine salvage. Interestingly, in cells lacking MetAP1, excess methionine dramatically inhibits cell growth. Growth inhibition is independent of the ability of methionine to repress MET genes and does not result from inhibition of synthesis of another metabolite, rather it results from product inhibition of MetAP2. Inhibition by methionine is selective for MetAP2 over MetAP1. These results provide an explanation for the previously observed dominance of MetAP1 in terms of N-terminal processing and cell growth in yeast. Additionally, differential regulation of the two isoforms may be indicative of different intracellular roles for the two enzymes.     

Expression of methionine aminopeptidase 2, N-myristoyltransferase, and N-myristoyltransferase inhibitor protein 71 in HT29

Protein myristoylation is a co-translational process, catalyzed by N-myristoyltransferase (NMT) that occurs after the initiating methionine is removed by methionine aminopeptidase (MetAP). The enzymes NMT and MetAP play a major role in the process of myristoylation of oncoproteins including the c-src family. In this study, we examined the levels of expression of MetAP2, NMT, and NMT inhibitor protein 71 (NIP71) in human colon cancer cell lines (HCCLs). We examined the influence of cell density on the expression of the above proteins in HT29 cells. Western blot analysis of MetAP2 and NMT demonstrated higher levels of protein expression in low density of HT29 while low expression in high density was observed. In addition, we observed that NIP71 and pp60(c-src) expressions were dependent on the cell density of HT29. This is the first study demonstrating the expression of MetAP2, NMT, pp60(c-src), and NIP71 in HCCLs.     

Physiologically relevant metal cofactor for methionine aminopeptidase-2 is manganese

The identity of the physiological metal cofactor for human methionine aminopeptidase-2 (MetAP2) has not been established. To examine this question, we first investigated the effect of eight divalent metal ions, including Ca(2+), Co(2+), Cu(2+), Fe(2+), Mg(2+), Mn(2+), Ni(2+), and Zn(2+), on recombinant human methionine aminopeptidase apoenzymes in releasing N-terminal methionine from three peptide substrates: MAS, MGAQFSKT, and (3)H-MASK(biotin)G. The activity of MetAP2 on either MAS or MGAQFSKT was enhanced 15-25-fold by Co(2+) or Mn(2+) metal ions in a broad concentration range (1-1000 microM). In the presence of reduced glutathione to mimic the cellular environment, Co(2+) and Mn(2+) were also the best stimulators (approximately 30-fold) for MetAP2 enzyme activity. To determine which metal ion is physiologically relevant, we then tested inhibition of intracellular MetAP2 with synthetic inhibitors selective for MetAP2 with different metal cofactors. A-310840 below 10 microM did not inhibit the activity of MetAP2-Mn(2+) but was very potent against MetAP2 with other metal ions including Co(2+), Fe(2+), Ni(2+), and Zn(2+) in the in vitro enzyme assays. In contrast, A-311263 inhibited MetAP2 with Mn(2+), as well as Co(2+), Fe(2+), Ni(2+), and Zn(2+). In cell culture assays, A-310840 did not inhibit intracellular MetAP2 enzyme activity and did not inhibit cell proliferation despite its ability to permeate and accumulate in cytosol, while A-311263 inhibited both intracellular MetAP2 and proliferation in a similar concentration range, indicating cellular MetAP2 is functioning as a manganese enzyme but not as a cobalt, zinc, iron, or nickel enzyme. We conclude that MetAP2 is a manganese enzyme and that therapeutic MetAP2 inhibitors should inhibit MetAP2-Mn(2+).     

Methionine aminopeptidase 2 is a new target for the metastasis-associated protein, S100A4

S100A4 is an EF-hand type calcium-binding protein that regulates tumor metastasis and a variety of cellular processes via interaction with different target proteins. Here we report that S100A4 physically interacts with methionine aminopeptidase 2 (MetAP2), the primary target for potent angiogenesis inhibitors, fumagillin and ovalicin. Using a yeast two-hybrid screen, S100A4 was found to interact with the N-terminal half of MetAP2. In vitro pull-down assays showed that S100A4 associates with MetAP2 in a calcium-dependent manner. In addition, the binding site of S100A4 was found located within the region between amino acid residues 170 and 229 of MetAP2. In vivo interaction of S100A4 with MetAP2 was verified by co-immunoprecipitation analysis. Immunofluorescent staining revealed that S100A4 and MetAP2 were co-localized in both quiescent and basic fibroblast growth factor-treated murine endothelial MSS31 cells, in the latter of which a significant change of intracellular distribution of both proteins was observed. Although the binding of S100A4 did not affect the in vitro methionine aminopeptidase activity of MetAP2, the cytochemical observation suggests a possible involvement of S100A4 in the regulation of MetAP2 activity through changing its localization, thereby modulating the N-terminal methionine processing of nascent substrates. These results may offer an essential clue for understanding the functional role of S100A4 in regulating endothelial cell growth and tumor metastasis.     

Selective inhibition of endothelial cell proliferation by fumagillin is not due to differential expression of methionine aminopeptidases

The angiogenesis inhibitors fumagillin and TNP-470 selectively inhibit the proliferation of endothelial cells, as compared with most other cell types. The mechanism of this selective inhibition remains uncertain, although methionine aminopeptidase-2 (MetAP2) has recently been found to be a target for fumagillin or TNP-470, which inactivates MetAP2 enzyme activity through covalent modification. Primary cultures of human endothelial cells and six other non-endothelial cell types were treated with fumagillin to determine its effect on cell proliferation. Only the growth of endothelial cells was completely inhibited at low concentrations of fumagillin. MetAP1 and MetAP2 levels in these cells were investigated to determine whether differential enzyme expression plays a role in the selective action of fumagillin. Western blot analysis and RT-PCR data showed that MetAP1 and MetAP2 were both expressed in these different types of cells, thus, ruling out differential expression of MetAP1 and MetAP2 as an explanation for the cell specificity of fumagillin. Expression of MetAP2, but not of MetAP1, is regulated. Treatment of human microvascular endothelial cells (HMVEC) with fumagillin resulted in threefold increases of MetAP2 protein in the cells, while MetAP1 remained constant. Similar upregulation of MetAP2 by exposure to fumagillin was also observed in non-endothelial cells, eliminating this response as an explanation for cell specificity. Taken together, these results indicate that while MetAP2 plays a critical role in the effect of fumagillin on endothelial cell proliferation, differential endogenous expression or fumagillin-induced upregulation of methionine aminopeptidases is not responsible for this observed selective inhibition.     

The specificity in vivo of two distinct methionine aminopeptidases in Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, the essential function of amino-terminal methionine removal is provided cotranslationally by two methionine aminopeptidases (MetAP1 and MetAP2). To examine the individual processing efficiency of each MetAP in vivo, we measured the degree of N-terminal methionine cleavage from a series of mutated glutathione-S-transferase (GST) proteins isolated from yeast wild-type, a map1 deletion strain, a map2 deletion strain, and a map1 deletion strain overexpressing the MAP2 gene. We found that MetAP1 plays the major role in N-terminal methionine removal in yeast. Both MetAPs were less efficient when the second residue was Val, and MetAP2 was less efficient than MetAP1 when the second residue was Gly, Cys, or Thr. These findings indicate that MetAP1 and MetAP2 exhibit different cleavage efficiencies against the same substrates in vivo. Interestingly, although methionine is considered a stabilizing N-terminal residue, we found that retention of the initiator methionine on the Met-Ala-GST mutant protein drastically reduced its half-life in vivo.     

A single amino acid difference between archaeal and human type 2 methionine aminopeptidases differentiates their affinity towards ovalicin

In almost all living cells, methionine aminopeptidase (MetAP) co-translationally cleaves the initiator methionine in at least 70% of the newly synthesized polypeptides. MetAPs are typically classified into Type 1 and Type 2. While prokaryotes and archaea contain only either Type 1 or Type 2 MetAPs respectively, eukaryotes contain both types of enzymes. Almost all MetAPs published till date cleave only methionine from the amino terminus of the substrate peptides. Earlier experiments on crude Type 2a MetAP isolated from Pyrococcus furiosus (PfuMetAP2a) cosmid protein library was shown to cleave leucine in addition to methionine. Authors in that study have ruled out the PfuMetAP2a activity against leucine substrates and assumed it to be a background reaction contributed by other contaminating proteases. In the current paper, using the pure recombinant enzyme, we report that indeed activity against leucine is directly carried out by the PfuMetAP2a. In addition, the natural product ovalicin which is a specific covalent inhibitor of Type 2 MetAPs does not show efficient inhibition against the PfuMetAP2a. Bioinformatic analysis suggested that a glycine in eukaryotic MetAP2s (G222 in human MetAP2b) and asparagine (N53 in PfuMetAP2a) in archaeal MetAP2s positioned at the analogous position. N53 side chain forms a hydrogen bond with a conserved histidine (H62) at the entrance of the active site and alters its orientation to accommodate the ovalicin. This slight orientational difference of the H62, reduces affinity of the ovalicin by 300,000-fold when compared with the HsMetAP2b inhibition. This difference in the activity is partly reduced in the case of N53G mutation of the PfuMetAP2a.     

Evidence of a dominant negative mutant of yeast methionine aminopeptidase type 2 in Saccharomyces cerevisiae

Eukaryotic methionine aminopeptidase type 2 (MetAP2, MetAP2 gene (MAP2)), together with eukaryotic MetAP1, cotranslationally hydrolyzes initiator methionine from nascent polypeptides when the side chain of the second residue is small and uncharged. In this report, we took advantage of the yeast (Saccharomyces cerevisiae) map1 null strain's reliance on MetAP2 activity for the growth and viability to provide evidence of the first dominant negative mutant of eukaryotic MetAP2. Replacement of the conserved His(174) with alanine within the C-terminal catalytic domain of yeast MetAP2 eliminated detectable catalytic activity against a peptide substrate in vitro. Overexpression of MetAP2 (H174A) under the strong GPD promoter in a yeast map1 null strain was lethal, whereas overexpression under the weaker GAL1 promoter slightly inhibited map1 null growth. Deletion mutants further revealed that the N-terminal region of MetAP2 (residues 2-57) is essential but not sufficient for MetAP2 (H174A) to fully interfere with map1 null growth. Together, these results indicate that catalytically inactive MetAP2 is a dominant negative mutant that requires its N-terminal region to interfere with wild-type MetAP2 function.     

Redox Regulation of Methionine Aminopeptidase 2 Activity

Protein translation is initiated with methionine in eukaryotes, and the majority of proteins have their N-terminal methionine removed by methionine aminopeptidases (MetAP1 and MetAP2) prior to action. Methionine removal can be important for protein function, localization, or stability. No mechanism of regulation of MetAP activity has been identified. MetAP2, but not MetAP1, contains a single Cys²²⁸-Cys⁴⁴⁸ disulfide bond that has an −RHStaple configuration and links two β-loop structures, which are hallmarks of allosteric disulfide bonds. From analysis of crystal structures and using mass spectrometry and activity assays, we found that the disulfide bond exists in oxidized and reduced states in the recombinant enzyme. The disulfide has a standard redox potential of −261 mV and is efficiently reduced by the protein reductant, thioredoxin, with a rate constant of 16,180 m⁻¹ s⁻¹. The MetAP2 disulfide bond also exists in oxidized and reduced states in glioblastoma tumor cells, and stressing the cells by oxygen or glucose deprivation results in more oxidized enzyme. The Cys²²⁸-Cys⁴⁴⁸ disulfide is at the rim of the active site and is only three residues distant from the catalytic His²³¹, which suggested that cleavage of the bond would influence substrate hydrolysis. Indeed, oxidized and reduced isoforms have different catalytic efficiencies for hydrolysis of MetAP2 peptide substrates. These findings indicate that MetAP2 is post-translationally regulated by an allosteric disulfide bond, which controls substrate specificity and catalytic efficiency.     

3-Amino-2-hydroxyamides and related compounds as inhibitors of methionine aminopeptidase-2

Substituted 3-amino-2-hydroxyamides and related hydroxyamides and acylhydrazines were identified as inhibitors of human methionine aminopeptidase-2 (MetAP2). Examination of substituents through parallel synthesis and iterative structure-based design allowed the identification of potent inhibitors with good selectivity against MetAP1. Diacylhydrazine 3t (A-357300) was identified as an analogue displaying inhibition of methionine processing and cellular proliferation in human microvascular endothelial cells (HMVEC).     

Discovery, identification, and characterization of candidate pharmacodynamic markers of methionine aminopeptidase-2 inhibition

The catalytic activity of methionine aminopeptidase-2 (MetAP2) has been pharmacologically linked to cell growth, angiogenesis, and tumor progression, making this an attractive target for cancer therapy. An assay for monitoring specific protein changes in response to MetAP2 inhibition, allowing pharmacokinetic (PK)/pharmacodynamic (PD) models to be established, could dramatically improve clinical decision-making. Candidate MetAP2-specific protein substrates were discovered from undigested cell culture-derived proteomes by MALDI-/SELDI-MS profiling and a biochemical method using (35)S-Met labeled protein lysates. Substrates were identified either as intact proteins by FT-ICR-MS or applying in-gel protease digestions followed by LC-MS/MS. The combination of these approaches led to the discovery of novel MetAP2-specific substrates including thioredoxin-1 (Trx-1), SH3 binding glutamic acid rich-like protein (SH3BGRL), and eukaryotic elongation factor-2 (eEF2). These studies also confirmed glyceraldehye 3-phosphate dehydrogenase (GAPDH) and cyclophillin A (CypA) as MetAP2 substrates. Additional data in support of these proteins as MetAP2-specific substrates were provided by in vitro MetAP1/MetAP2 enzyme assays with the corresponding N-terminal derived peptides and 1D/2D Western analyses of cellular and tissue lysates. FT-ICR-MS characterization of all intact species of the 18 kDa substrate, CypA, enabled a SELDI-MS cell-based assay to be developed for correlating N-terminal processing and inhibition of proliferation. The MetAP2-specific protein substrates discovered in this study have diverse properties that should facilitate the development of reagents for testing in preclinical and clinical environments.     

Pyridinylpyrimidines selectively inhibit human methionine aminopeptidase-1

Cellular protein synthesis is initiated with methionine in eukaryotes with few exceptions. Methionine aminopeptidases (MetAPs) which catalyze the process of N-terminal methionine excision are essential for all organisms. In mammals, type 2 MetAP (MetAP2) is known to be important for angiogenesis, while type 1 MetAP (MetAP1) has been shown to play a pivotal role in cell proliferation. Our previous high-throughput screening of a commercial compound library uncovered a novel class of inhibitors for both human MetAP1 (HsMetAP1) and human MetAP2 (HsMetAP2). This class of inhibitors contains a pyridinylpyrimidine core. To understand the structure–activity relationship (SAR) and to search for analogues of 2 with greater potency and higher HsMetAP1-selectivity, a total of 58 analogues were acquired through either commercial source or by in-house synthesis and their inhibitory activities against HsMetAP1 and HsMetAP2 were determined. Through this systematic medicinal chemistry analysis, we have identified (1) 5-chloro-6-methyl-2-pyridin-2-ylpyrimidine as the minimum element for the inhibition of HsMetAP1; (2) 5′-chloro as the favored substituent on the pyridine ring for the enhanced potency against HsMetAP1; and (3) long C4 side chains as the essentials for higher HsMetAP1-selectivity. At the end of our SAR campaign, 25b, 25c, 26d and 30a–30c are among the most selective and potent inhibitors of purified HsMetAP1 reported to date. In addition, we also performed crystallographic analysis of one representative inhibitor (26d) in complex with N-terminally truncated HsMetAP1.     

Roles of P67/MetAP2 as a tumor suppressor

A precise balance between growth promoting signals and growth inhibitory signals plays important roles in the maintenance of healthy mammalian cells. Any deregulation of this critical balance converts normal cells into abnormal or cancerous cells. Several macromolecules are being identified and characterized that are involved in the regulation of cell signaling pathways that connect to the cell cycle and thus they play roles as tumor promoters or tumor suppressors. In situ tumor formation needs active angiogenesis, a process that generates new blood vessels from existing ones either by splitting or sprouting. Several small molecule inhibitors and proteins have been identified as inhibitors of angiogenesis. One such protein, p67/MetAP2 also known as methionine aminopeptidase 2 (MetAP2), has been shown to bind covalently to fumagillin and its derivatives that have anti-angiogenic activity. In addition to fumagillin or its derivatives, several other small molecule inhibitors of p67/MetAP2 have been recently identified and some of these drugs are in phase III trials for cancer therapy. Although molecular details of actions toward tumor suppression by these drugs are largely unknown, a significant progress has been made to understand the structure–function relationship of p67/MetAP2 and its roles in the maintenance of the levels of phosphorylation of the ∝-subunit of eukaryotic initiation factor 2 (eIF2∝) and extracellular signal-regulated kinases 1 and 2 (ERK1/2). In this article, roles of p67/MetAP2 in the suppression of cancer development are also discussed.     

Angiogenesis inhibitors specific for methionine aminopeptidase 2 as drugs for Malaria and Leishmaniasis

Methionine aminopeptidase 2 (MetAP2) is responsible for the hydrolysis of the initiator methionine molecule from the majority of newly synthesized proteins. We have cloned the MetAP2 gene from the malaria parasite Plasmodium falciparum (PfMetAP2; GenBank accession number AF348320). The cloned PfMetAP2 has no intron, consists of 1,544 bp and encodes a protein of 354 amino acids with a molecular mass of 40,537 D and an overall base composition of 72.54% A + T. PfMetAP2 has 40% sequence identity with human MetAP2 and 45% identity with yeast MetAP2, and is located in chromosome 14 of P. falciparum. The three-dimensional structure of Pf MetAP2 has been modeled based on the crystal structure of human MetAP2, and several amino acid side chains protruding into the binding pocket that differ between the plasmodial and human enzyme have been identified. The specific MetAP2 inhibitors, fumagillin and TNP-470, potently blocked in vitro growth of P. falciparum and Leishmania donavani, with IC(50) values similar to the prototype drugs. Furthermore, in the case of P. falciparum, the chloroquine-resistant strains are equally susceptible to these two compounds.     

Methionine aminopeptidase 2 and cancer

Methionine aminopeptidase (MetAP) is a bifunctional protein that plays a critical role in the regulation of post-translational processing and protein synthesis. In yeasts and humans, two proteins are known to possess MetAP activity, which are known as MetAP1 and MetAP2. MetAP2 has attracted much more attention than MetAP1 due to the discovery of MetAP2 as a target molecule of the anti-angiogenic compounds, fumallin and ovalicin. MetAP2 plays an important role in the development of different types of cancer. Recently, we observed a high expression of MetAP2 in human colorectal cancer tissues and colon cancer cell lines. In addition, pp60(c-src) expression was correlated with the expression of MetAP2 and N-myristoyltransferase. In this review, we discuss the recent developments of MetAP2 and its inhibitors. Future detailed studies related to MetAP2 and apoptosis will shed light on the involvement of this enzyme in the regulation of various apoptotic factors.     

Yeast glutamine-fructose-6-phosphate aminotransferase (Gfa1) requires methionine aminopeptidase activity for proper function

Methionine aminopeptidase (MetAP) catalyzes the co-translational processing of initiator methionine from nascent proteins. A cellular requirement for MetAP activity is likely due to dysfunction of MetAP substrates that require methionine removal for proper protein function. Glutamine-fructose-6-phosphate aminotransferase (Gfa1) is an essential enzyme in yeast that catalyzes the first and rate-limiting step in hexosamine biosynthesis. The alpha-amino group of Gfa1 Cys-1 has been proposed to act as a nucleophile in the catalytic mechanism. We used two mutational strategies to evaluate whether removal of initiator methionine, catalyzed by MetAP, is required for Gfa1 function. Our results demonstrate that exposure of the alpha-amino group of Cys-1 is required for normal Gfa1 function as failure to do so results in decreased enzyme activity and slow growth. Further, either isoform of MetAP in yeast is sufficient for Gfa1 processing in vivo. These results are the first demonstration of an endogenous yeast protein that requires the exposure of the alpha-amino group by MetAP action for normal function. Additionally, Gfa1 will be a relevant target in therapeutic or physiological applications in which MetAP activity is inhibited.     

Two continuous spectrophotometric assays for methionine aminopeptidase

Two spectrophotometric assays have been developed for methionine aminopeptidases (MetAPs). The first method employs a thioester substrate which, upon enzymatic removal of the N-terminal methionine, generates a free thiol group. The released thiol is quantitated using Ellman's reagent. The MetAP reaction is conveniently monitored on a UV-VIS spectrophotometer in a continuous fashion, with the addition of an excess of Ellman's reagent into the assay reaction. Two tripeptide analogues were synthesized and found to be excellent substrates of both Escherichia coli MetAP and human MetAP2 (k(cat)/K(M) = 2.8 x 10(5) M(-1) s(-1) for the most reactive substrate). In the second assay method, the MetAP reaction is coupled to a prolyl aminopeptidase reaction using Met-Pro-p-nitroanilide as substrate. MetAP-catalyzed cleavage of the N-terminal methionine produces prolyl-p-nitroanilide, which is rapidly hydrolyzed by the prolyl aminopeptidase from Bacillus coagulans to release a chromogenic product, p-nitroaniline. This allows the MetAP reaction to be continuously monitored at 405 nm on a UV-VIS spectrophotometer. The assays have been applied to determine the pH optima and kinetic constants for the E. coli and human MetAPs as well as to screen MetAP inhibitors. These results demonstrate that the current assays are convenient, rapid, and sensitive methods for kinetic studies of MetAPs and effective tools for screening MetAP inhibitors.     

FE(II) is the native cofactor for Escherichia coli methionine aminopeptidase

Divalent metal ions play a critical role in the removal of N-terminal methionine from nascent proteins by methionine aminopeptidase (MetAP). Being an essential enzyme for bacteria, MetAP is an appealing target for the development of novel antibacterial drugs. Although purified enzyme can be activated by several divalent metal ions, the exact metal ion used by MetAP in cells is unknown. Many MetAP inhibitors are highly potent on purified enzyme, but they fail to show significant inhibition of bacterial growth. One possibility for the failure is a disparity of the metal used in activation of purified MetAP and the metal actually used by MetAP inside bacterial cells. Therefore, the challenge is to elucidate the physiologically relevant metal for MetAP and discover MetAP inhibitors that can effectively inhibit cellular MetAP. We have recently discovered MetAP inhibitors with selectivity toward different metalloforms of Escherichia coli MetAP, and with these unique inhibitors, we characterized their inhibition of MetAP enzyme activity in a cellular environment. We observed that only inhibitors that are selective for the Fe(II)-form of MetAP were potent in this assay. Further, we found that only these Fe(II)-form selective inhibitors showed significant inhibition of growth of five E. coli strains and two Bacillus strains. We confirmed their cellular target as MetAP by analysis of N-terminal processed and unprocessed recombinant glutathione S-transferase proteins. Therefore, we conclude that Fe(II) is the likely metal used by MetAP in E. coli and other bacterial cells.     

The CRL2LRR-1 ubiquitin ligase regulates cell cycle progression during C. elegans development

The molecular mechanisms that regulate cell cycle progression in a developmental context are poorly understood. Here, we show that the leucine-rich repeat protein LRR-1 promotes cell cycle progression during C. elegans development, both in the germ line and in the early embryo. Our results indicate that LRR-1 acts as a nuclear substrate-recognition subunit of a Cullin 2-RING E3 ligase complex (CRL2(LRR-1)), which ensures DNA replication integrity. LRR-1 contains a typical BC/Cul-2 box and binds CRL2 components in vitro and in vivo in a BC/Cul-2 box-dependent manner. Loss of lrr-1 function causes cell cycle arrest in the mitotic region of the germ line, resulting in sterility due to the depletion of germ cells. Inactivation of the DNA replication checkpoint signaling components ATL-1 and CHK-1 suppresses this cell cycle arrest and, remarkably, restores lrr-1 mutant fertility. Likewise, in the early embryo, loss of lrr-1 function induces CHK-1 phosphorylation and a severe cell cycle delay in P lineage division, causing embryonic lethality. Checkpoint activation is not constitutive in lrr-1 mutants but is induced by DNA damage, which may arise due to re-replication of some regions of the genome as evidenced by the accumulation of single-stranded DNA-replication protein A (ssDNA-RPA-1) nuclear foci and the increase in germ cell ploidy in lrr-1 and lrr-1; atl-1 double mutants, respectively. Collectively, these observations highlight a crucial function of the CRL2(LRR-1) complex in genome stability via maintenance of DNA replication integrity during C. elegans development.