Proinsulin and the Genetics of Diabetes Mellitus

Insulin plays a central role in the regulation of vertebrate metabolism. The hormone, the post-translational product of a single-chain precursor, is a globular protein containing two chains, A (21 residues) and B (30 residues). Recent advances in human genetics have identified dominant mutations in the insulin gene causing permanent neonatal-onset DM² (1–4). The mutations are predicted to block folding of the precursor in the ER of pancreatic β-cells. Although expression of the wild-type allele would in other circumstances be sufficient to maintain homeostasis, studies of a corresponding mouse model (5–7) suggest that the misfolded variant perturbs wild-type biosynthesis (8, 9). Impaired β-cell secretion is associated with ER stress, distorted organelle architecture, and cell death (10). These findings have renewed interest in insulin biosynthesis (11–13) and the structural basis of disulfide pairing (14–19). Protein evolution is constrained not only by structure and function but also by susceptibility to toxic misfolding.Insulin plays a central role in the regulation of vertebrate metabolism. The hormone, the post-translational product of a single-chain precursor, is a globular protein containing two chains, A (21 residues) and B (30 residues). Recent advances in human genetics have identified dominant mutations in the insulin gene causing permanent neonatal-onset DM² (1–4). The mutations are predicted to block folding of the precursor in the ER of pancreatic β-cells. Although expression of the wild-type allele would in other circumstances be sufficient to maintain homeostasis, studies of a corresponding mouse model (5–7) suggest that the misfolded variant perturbs wild-type biosynthesis (8, 9). Impaired β-cell secretion is associated with ER stress, distorted organelle architecture, and cell death (10). These findings have renewed interest in insulin biosynthesis (11–13) and the structural basis of disulfide pairing (14–19). Protein evolution is constrained not only by structure and function but also by susceptibility to toxic misfolding.     

Pif1 Helicase Lengthens Some Okazaki Fragment Flaps Necessitating Dna2 Nuclease/Helicase Action in the Two-nuclease Processing Pathway

We have developed a system to reconstitute all of the proposed steps of Okazaki fragment processing using purified yeast proteins and model substrates. DNA polymerase δ was shown to extend an upstream fragment to displace a downstream fragment into a flap. In most cases, the flap was removed by flap endonuclease 1 (FEN1), in a reaction required to remove initiator RNA in vivo. The nick left after flap removal could be sealed by DNA ligase I to complete fragment joining. An alternative pathway involving FEN1 and the nuclease/helicase Dna2 has been proposed for flaps that become long enough to bind replication protein A (RPA). RPA binding can inhibit FEN1, but Dna2 can shorten RPA-bound flaps so that RPA dissociates. Recent reconstitution results indicated that Pif1 helicase, a known component of fragment processing, accelerated flap displacement, allowing the inhibitory action of RPA. In results presented here, Pif1 promoted DNA polymerase δ to displace strands that achieve a length to bind RPA, but also to be Dna2 substrates. Significantly, RPA binding to long flaps inhibited the formation of the final ligation products in the reconstituted system without Dna2. However, Dna2 reversed that inhibition to restore efficient ligation. These results suggest that the two-nuclease pathway is employed in cells to process long flap intermediates promoted by Pif1.Eukaryotic cellular DNA is replicated semi-conservatively in the 5′ to 3′ direction. A leading strand is synthesized by DNA polymerase ϵ in a continuous manner in the direction of opening of the replication fork (1, 2). A lagging strand is synthesized by DNA polymerase δ (pol δ)³ in the opposite direction in a discontinuous manner, producing segments called Okazaki fragments (3). These stretches of ∼150 nucleotides (nt) must be joined together to create the continuous daughter strand. DNA polymerase α/primase (pol α) initiates each fragment by synthesizing an RNA/DNA primer consisting of ∼1-nt of RNA and ∼10–20 nt of DNA (4). The sliding clamp proliferating cell nuclear antigen (PCNA) is loaded on the DNA by replication factor C (RFC). pol δ then complexes with PCNA and extends the primer. When pol δ reaches the 5′-end of the downstream Okazaki fragment, it displaces the end into a flap while continuing synthesis, a process known as strand displacement (5, 6). These flap intermediates are cleaved by nucleases to produce a nick for DNA ligase I (LigI) to seal, completing the DNA strand.In one proposed mechanism for flap processing, the only required nuclease is flap endonuclease 1 (FEN1). pol δ displaces relatively short flaps, which are cleaved by FEN1 as they are created, leaving a nick for LigI (7–9). FEN1 binds at the 5′-end of the flap and tracks down the flap cleaving only at the base (5, 10, 11). Because pol δ favors the displacement of RNA-DNA hybrids over DNA-DNA hybrids, strand displacement generally is limited to that of the initiator RNA of an Okazaki fragment (12). In addition, the tightly coordinated action of pol δ and FEN1 also tends to keep flaps short. However, biochemical reconstitution studies demonstrate that some flaps can become long (13, 14). Once these flaps reach ∼30 nt, they can be bound by the eukaryotic single strand binding protein replication protein A (RPA) (15). Binding by RPA to a flap substrate inhibits cleavage by FEN1 (16). The RPA-bound flap would then require another mechanism for proper processing.This second mechanism is proposed to utilize Dna2 (16) in addition to FEN1. Dna2 is both a 5′-3′ helicase and an endonuclease (17, 18). Like FEN1, Dna2 recognizes 5′-flap structures, binding at the 5′-end of the flap and tracking downward toward the base (19, 20). Unlike FEN1, Dna2 cleaves the flap multiple times but not all the way to the base, such that a short flap remains (20). RPA binding to a flap has been shown to stimulate Dna2 cleavage (16). Therefore, if a flap becomes long enough to bind RPA, Dna2 binds and cleaves it to a length of 5–10 nucleotides from which RPA dissociates (21). FEN1 can then enter the flap, displace the Dna2, and then cleave at the base to make the nick for ligation (16, 18, 22). The need for this mechanism may be one reason why DNA2 is an essential gene in Saccharomyces cerevisiae (23, 24). It has been proposed that, in the absence of Dna2, flaps that become long enough to bind RPA cannot be properly processed, leading to genomic instability and cell death (23).In reconstitution of Okazaki fragment processing with purified proteins, even though some flaps became long enough to bind RPA, FEN1 was very effective at cleaving essentially all of the generated flaps (13, 14). Evidently, FEN1 could engage the flaps before binding of RPA. However, these reconstitution assays did not include the 5′-3′ helicase Pif1 (25, 26). Pif1 is involved in telomeric and mitochondrial DNA maintenance (26) and was first implicated in Okazaki fragment processing from genetic studies in S. cerevisiae. Deletion of PIF1 rescued the lethality of dna2Δ, although the double mutant was still temperature-sensitive (27). The authors of this report proposed that Pif1 creates a need for Dna2 by promoting longer flaps. Further supporting this conclusion, deletion of POL32, which encodes the subunit of pol δ that interacts with PCNA, rescued the temperature sensitivity of the dna2Δpif1Δ double mutant (12, 27). Importantly, pol δ exhibited reduced strand displacement activity when POL32 was deleted (12, 28, 29). The combination of pif1Δ and pol32Δ is believed to create a situation in which virtually no long flaps are formed, eliminating the requirement for Dna2 flap cleavage (27).We recently performed reconstitution assays showing that Pif1 can assist in the creation of long flaps. Inclusion of Pif1, in the absence of RPA, increased the proportion of flaps that lengthened to ∼28–32 nt before FEN1 cleavage (14). With the addition of RPA, the appearance of these long flap cleavage products was suppressed. Evidently, Pif1 promoted such rapid flap lengthening that RPA bound some flaps before FEN1 and inhibited cleavage. The RPA-bound flaps would presumably require cleavage by Dna2 for proper processing.Only a small fraction of flaps became long with Pif1. However, there are hundreds of thousands of Okazaki fragments processed per replication cycle (30). Therefore, thousands of flaps are expected to be lengthened by Pif1 in vivo, a number significant enough that improper processing of such flaps could lead to cell death.Our goal here was to determine whether Pif1 can influence the flow of Okazaki fragments through the two proposed pathways. We first questioned whether Pif1 stimulates strand displacement synthesis by pol δ. Next, we asked whether Pif1 lengthens short flaps so that Dna2 can bind and cleave. Finally, we used a complete reconstitution system to determine whether Pif1 promotes creation of RPA-bound flaps that require cleavage by both Dna2 and FEN1 before they can be ligated. Our results suggest that Pif1 promotes the two-nuclease pathway, and reveal the mechanisms involved.     

In Vitro Characterization of a Recombinant Blh Protein from an Uncultured Marine Bacterium as a ��-Carotene 15,15��-Dioxygenase

Codon optimization was used to synthesize the blh gene from the uncultured marine bacterium 66A03 for expression in Escherichia coli. The expressed enzyme cleaved β-carotene at its central double bond (15,15′) to yield two molecules of all-trans-retinal. The molecular mass of the native purified enzyme was ∼64 kDa as a dimer of 32-kDa subunits. The K_m, k_cat, and k_cat/K_m values for β-carotene as substrate were 37 μm, 3.6 min⁻¹, and 97 mm⁻¹ min⁻¹, respectively. The enzyme exhibited the highest activity for β-carotene, followed by β-cryptoxanthin, β-apo-4′-carotenal, α-carotene, and γ-carotene in decreasing order, but not for β-apo-8′-carotenal, β-apo-12′-carotenal, lutein, zeaxanthin, or lycopene, suggesting that the presence of one unsubstituted β-ionone ring in a substrate with a molecular weight greater than C₃₅ seems to be essential for enzyme activity. The oxygen atom of retinal originated not from water but from molecular oxygen, suggesting that the enzyme was a β-carotene 15,15′-dioxygenase. Although the Blh protein and β-carotene 15,15′-monooxygenases catalyzed the same biochemical reaction, the Blh protein was unrelated to the mammalian β-carotene 15,15′-monooxygenases as assessed by their different properties, including DNA and amino acid sequences, molecular weight, form of association, reaction mechanism, kinetic properties, and substrate specificity. This is the first report of in vitro characterization of a bacterial β-carotene-cleaving enzyme.Vitamin A (retinol) is a fat-soluble vitamin and important for human health. In vivo, the cleavage of β-carotene to retinal is an important step of vitamin A synthesis. The cleavage can proceed via two different biochemical pathways (1, 2). The major pathway is a central cleavage catalyzed by mammalian β-carotene 15,15′-monooxygenases (EC 1.14.99.36). β-Carotene is cleaved by the enzyme symmetrically into two molecules of all-trans-retinal, and retinal is then converted to vitamin A in vivo (3–5). The second pathway is an eccentric cleavage that occurs at double bonds other than the central 15,15′-double bond of β-carotene to produce β-apo-carotenals with different chain lengths, which are catalyzed by carotenoid oxygenases from mammals, plants, and cyanobacteria (6). These β-apo-carotenals are degraded to one molecule of retinal, which is subsequently converted to vitamin A in vivo (2).β-Carotene 15,15′-monooxygenase was first isolated as a cytosolic enzyme by identifying the product of β-carotene cleavage as retinal (7). The characterization of the enzyme and the reaction pathway from β-carotene to retinal were also investigated (4, 8). The enzyme activity has been found in mammalian intestinal mucosa, jejunum enterocytes, liver, lung, kidney, and brain (5, 9, 10). Molecular cloning, expression, and characterization of β-carotene 15,15′-monooxygenase have been reported from various species, including chickens (11), fruit flies (12), humans (13), mice (14), and zebra fishes (15).Other proteins thought to convert β-carotene to retinal include bacterioopsin-related protein (Brp) and bacteriorhodopsin-related protein-like homolog protein (Blh) (16). Brp protein is expressed from the bop gene cluster, which encodes the structural protein bacterioopsin, consisting of at least three genes as follows: bop (bacterioopsin), brp (bacteriorhodopsin-related protein), and bat (bacterioopsin activator) (17). brp genes were reported in Haloarcula marismortui (18), Halobacterium sp. NRC-1 (19), Halobacterium halobium (17), Haloquadratum walsbyi, and Salinibacter ruber (20). Blh protein is expressed from the proteorhodopsin gene cluster, which contains proteorhodopsin, crtE (geranylgeranyl-diphosphate synthase), crtI (phytoene dehydrogenase), crtB (phytoene synthase), crtY (lycopene cyclase), idi (isopentenyl diphosphate isomerase), and blh gene (21). Sources of blh genes were previously reported in Halobacterium sp. NRC-1 (19), Haloarcula marismortui (18), Halobacterium salinarum (22), uncultured marine bacterium 66A03 (16), and uncultured marine bacterium HF10 49E08 (21). β-Carotene biosynthetic genes crtE, crtB, crtI, crtY, ispA, and idi encode the enzymes necessary for the synthesis of β-carotene from isopentenyl diphosphate, and the Idi, IspA, CrtE, CrtB, CrtI, and CrtY proteins have been characterized in vitro (23–28). Blh protein has been proposed to catalyze or regulate the conversion of β-carotene to retinal (29, 30), but there is no direct proof of the enzymatic activity.In this study, we used codon optimization to synthesize the blh gene from the uncultured marine bacterium 66A03 for expression in Escherichia coli, and we performed a detailed biochemical and enzymological characterization of the expressed Blh protein. In addition, the properties of the enzyme were compared with those of mammalian β-carotene 15,15′-monooxygenases.     

Reconstitution of Uracil DNA Glycosylase-initiated Base Excision Repair in Herpes Simplex Virus-1

Herpes simplex virus-1 is a large double-stranded DNA virus that is self-sufficient in a number of genome transactions. Hence, the virus encodes its own DNA replication apparatus and is capable of mediating recombination reactions. We recently reported that the catalytic subunit of the HSV-1 DNA polymerase (UL30) exhibits apurinic/apyrimidinic and 5′-deoxyribose phosphate lyase activities that are integral to base excision repair. Base excision repair is required to maintain genome stability as a means to counter the accumulation of unusual bases and to protect from the loss of DNA bases. Here we have reconstituted a system with purified HSV-1 and human proteins that perform all the steps of uracil DNA glycosylase-initiated base excision repair. In this system nucleotide incorporation is dependent on the HSV-1 uracil DNA glycosylase (UL2), human AP endonuclease, and the HSV-1 DNA polymerase. Completion of base excision repair can be mediated by T4 DNA ligase as well as human DNA ligase I or ligase IIIα-XRCC1 complex. Of these, ligase IIIα-XRCC1 is the most efficient. Moreover, ligase IIIα-XRCC1 confers specificity onto the reaction in as much as it allows ligation to occur in the presence of the HSV-1 DNA polymerase processivity factor (UL42) and prevents base excision repair from occurring with heterologous DNA polymerases. Completion of base excision repair in this system is also dependent on the incorporation of the correct nucleotide. These findings demonstrate that the HSV-1 proteins in combination with cellular factors that are not encoded by the virus are capable of performing base excision repair. These results have implications on the role of base excision repair in viral genome maintenance during lytic replication and reactivation from latency.Herpes simplex virus-1 (HSV-1)² is a large double-stranded DNA virus with a genome of ∼152 kilobase pairs (for reviews, see Refs. 1 and 2). HSV-1 switches between lytic replication in epithelial cells and a state of latency in sensory neurons during which there is no detectable DNA replication (1). Viral DNA replication is mediated by seven essential virus-encoded factors (3–5). Of these, two encode subunits of the viral replicase (for review, see Refs. 6 and 7). The catalytic subunit (UL30) exhibits DNA polymerase (Pol), 3′-5′ proofreading exonuclease, and RNase H activities (8–11). UL30 exists as a heterodimer with the UL42 protein that confers a high degree of processivity on the Pol (11–17).Viral DNA replication is accompanied by vigorous recombination that leads to the formation of large networks of viral DNA replication intermediates (18). The HSV-1 single-strand DNA-binding protein (ICP8) has been shown to play a major role in mediating these recombination reactions (19–21). One role for the high frequency of recombination is to restart DNA replication at sites of fork collapse. Further mechanisms that contribute to genome maintenance are processes that survey and repair damage to the DNA to ensure the availability of a robust replication template. In this regard base excision repair (BER) is essential to remove unusual bases from the DNA and to repair apurinic/apyrimidinic (AP) sites resulting from spontaneous base loss (for review, see Ref. 22). With respect to HSV-1, a recent study showed that viral DNA from infected cultured fibroblasts contains a steady state of 2.8–5.9 AP sites per viral genome equivalent (23). Because AP sites are non-instructional, the failure to repair such sites would terminate viral replication. Indeed, UL30 cannot replicate beyond a model AP site (tetrahydrofuran residue) (23), indicating that the virus must enable a process to repair such lesions. In this regard HSV-1 possesses several enzymes that would safeguard from the accumulation of unusual bases, specifically uracil, and base loss. Hence, HSV-1 encodes a uracil DNA glycosylase (UDG) (UL2) as well as a dUTPase to reduce the pool of dUTP and prevent misincorporation by the viral Pol (24, 25). Moreover, we recently showed that the catalytic subunit of the viral Pol (UL30) exhibits AP and 5′-deoxyribose phosphate (dRP) lyase activities (26). The presence of a virus-encoded UDG and DNA lyase indicates that HSV-1 has the capacity to perform integral steps of BER, specifically for the removal of uracil. Indeed, the excision of uracil may be important for viral replication. Hence, it has been shown that uracil substitutions in the viral origins of replication alters their recognition by the viral initiator protein (27). Moreover, whereas UL2 may be dispensable for viral replication in fibroblast (24), UL2 mutants exhibit reduced neurovirulence and a decreased frequency of reactivation from latency (28). Thus, UDG action in HSV-1 may be important for viral reactivation after quiescence in neuronal cells during which the genome may accumulate uracil as a result of spontaneous deamination of cytosine. In another herpesvirus, cytomegalovirus, the viral UDG was shown to be required for the transition to late-phase DNA replication (29, 30). Consequently, it is possible that BER plays a significant role in various aspects of the herpesvirus life cycle.In mammalian single-nucleotide BER initiated by monofunctional DNA glycosylases, the resulting AP sites are incised hydrolytically at the 5′ side by AP endonuclease (APE), generating a 3′-OH. This is followed by template-directed incorporation of one nucleotide by Pol β to generate a 5′-dRP flap (22, 31, 32). The 5′-dRP residue is subsequently removed by the 5′-dRP lyase activity of Pol β to leave a nick with a 3′-OH and 5′-phosphate that is ligated by DNA ligase I or the physiologically more relevant ligase IIIα-XRCC1 complex (for review, see Refs. 33 and 34). Here we show that the HSV-1 UDG (UL2) and Pol (UL30) cooperate with human APE and human ligase IIIα-XRCC1 complex to perform BER in vitro. This finding has implications on the role of BER in viral genome maintenance during lytic replication and in the emergence of the virus from neuronal latency.