Human DNA polymerase iota promiscuous mismatch extension

Human DNA polymerase iota is a low-fidelity template copier that preferentially catalyzes the incorporation of the wobble base G, rather than the Watson-Crick base A, opposite template T (Tissier, A., McDonald, J. P., Frank, E. G., and Woodgate, R. (2000) Genes Dev. 14, 1642-1650; Johnson, R. E., Washington, M. T., Haracska, L., Prakash, S., and Prakash, L. (2000) Nature 406, 1015-1019; Zhang, Y., Yuan, F., Wu, X., and Wang, Z. (2000) Mol. Cell. Biol. 20, 7099-7108). Here, we report on its ability to extend all 12 possible mispairs and 4 correct pairs in different sequence contexts. Extension from both matched and mismatched primer termini is generally most efficient and accurate when A is the next template base. In contrast, extension occurs less efficiently and accurately when T is the target template base. A striking exception occurs during extension of a G:T mispair, where the enzyme switches specificity, "preferring" to make a correct A:T base pair immediately downstream from an originally favored G:T mispair. Polymerase iota generates a variety of single and tandem mispairs with high frequency, implying that it may act as a strong mutator when copying undamaged DNA templates in vivo. Even so, its limited ability to catalyze extension from a relatively stable primer/template containing a "buried" mismatch suggests that polymerase iota-catalyzed errors are confined to short template regions.

Roles of DNA polymerases V and II in SOS-induced error-prone and error-free repair in Escherichia coli

DNA polymerase V, composed of a heterotrimer of the DNA damage-inducible UmuC and UmuD(2)(') proteins, working in conjunction with RecA, single-stranded DNA (ssDNA)-binding protein (SSB), beta sliding clamp, and gamma clamp loading complex, are responsible for most SOS lesion-targeted mutations in Escherichia coli, by catalyzing translesion synthesis (TLS). DNA polymerase II, the product of the damage-inducible polB (dinA ) gene plays a pivotal role in replication-restart, a process that bypasses DNA damage in an error-free manner. Replication-restart takes place almost immediately after the DNA is damaged (approximately 2 min post-UV irradiation), whereas TLS occurs after pol V is induced approximately 50 min later. We discuss recent data for pol V-catalyzed TLS and pol II-catalyzed replication-restart. Specific roles during TLS for pol V and each of its accessory factors have been recently determined. Although the precise molecular mechanism of pol II-dependent replication-restart remains to be elucidated, it has recently been shown to operate in conjunction with RecFOR and PriA proteins.

Expression of error-prone polymerases in BL2 cells activated for Ig somatic hypermutation

High affinity antibodies are generated in mice and humans by means of somatic hypermutation (SHM) of variable (V) regions of Ig genes. Mutations with rates of 10(-5)--10(-3) per base pair per generation, about 10(6)-fold above normal, are targeted primarily at V-region hot spots by unknown mechanisms. We have measured mRNA expression of DNA polymerases iota, eta, and zeta by using cultured Burkitt's lymphoma (BL)2 cells. These cells exhibit 5-10-fold increases in heavy-chain V-region mutations targeted only predominantly to RGYW (R = A or G, Y = C or T, W = T or A) hot spots if costimulated with T cells and IgM crosslinking, the presumed in vivo requirements for SHM. An approximately 4-fold increase pol iota mRNA occurs within 12 h when cocultured with T cells and surface IgM crosslinking. Induction of pols eta and zeta occur with T cells, IgM crosslinking, or both stimuli. The fidelity of pol iota was measured at RGYW hot- and non-hot-spot sequences situated at nicks, gaps, and double-strand breaks. Pol iota formed T x G mispairs at a frequency of 10(-2), consistent with SHM-generated C to T transitions, with a 3-fold increased error rate in hot- vs. non-hot-spot sequences for the single-nucleotide overhang. The T cell and IgM crosslinking-dependent induction of pol iota at 12 h may indicate an SHM "triggering" event has occurred. However, pols iota, eta, and zeta are present under all conditions, suggesting that their presence is not sufficient to generate mutations because both T cell and IgM stimuli are required for SHM induction.

A new class of errant DNA polymerases provides candidates for somatic hypermutation

The mechanism of somatic hypermutation of the immunoglobulin genes remains a mystery after nearly 30 years of intensive research in the field. While many clues to the process have been discovered in terms of the genetic elements required in the immunoglobulin genes, the key enzymatic players that mediate the introduction of mutations into the variable region are unknown. The recent wave of newly discovered eukaryotic DNA polymerases have given a fresh supply of potential candidates and a renewed vigour in the search for the elusive mutator factor governing affinity maturation. In this paper, we discuss the relevant genetic and biochemical evidence known to date regarding both somatic hypermutation and the new DNA polymerases and address how the two fields can be brought together to identify the strongest candidates for further study. In particular we discuss evidence for the in vitro biochemical misincorporation properties of human Rad30B/Pol iota and how it compares to the in vivo somatic hypermutation spectra.

A model for SOS-lesion-targeted mutations in Escherichia coli

The UmuD'2C protein complex (Escherichia coli pol V) is a low-fidelity DNA polymerase (pol) that copies damaged DNA in the presence of RecA, single-stranded-DNA binding protein (SSB) and the beta,gamma-processivity complex of E. coli pol III (ref. 4). Here we propose a model to explain SOS-lesion-targeted mutagenesis, assigning specific biochemical functions for each protein during translesion synthesis. (SOS lesion-targeted mutagenesis occurs when pol V is induced as part of the SOS response to DNA damage and incorrectly incorporates nucleotides opposite template lesions.) Pol V plus SSB catalyses RecA filament disassembly in the 3' to 5' direction on the template, ahead of the polymerase, in a reaction that does not involve ATP hydrolysis. Concurrent ATP-hydrolysis-driven filament disassembly in the 5' to 3' direction results in a bidirectional stripping of RecA from the template strand. The bidirectional collapse of the RecA filament restricts DNA synthesis by pol V to template sites that are proximal to the lesion, thereby minimizing the occurrence of untargeted mutations at undamaged template sites.

The expanding polymerase universe

Over the past year, the number of known prokaryotic and eukaryotic DNA polymerases has exploded. Many of these newly discovered enzymes copy aberrant bases in the DNA template over which 'respectable' polymerases fear to tread. The next step is to unravel their functions, which are thought to range from error-prone copying of DNA lesions, somatic hypermutation and avoidance of skin cancer, to restarting stalled replication forks and repairing double-stranded DNA breaks.

Molecular mechanism and energetics of clamp assembly in Escherichia coli. The role of ATP hydrolysis when gamma complex loads beta on DNA

Escherichia coli DNA polymerase III holoenzyme is a multisubunit composite containing the beta sliding clamp and clamp loading gamma complex. The gamma complex requires ATP to load beta onto DNA. A two-color fluorescence spectroscopic approach was utilized to study this system, wherein both assembly (red fluorescence; X-rhodamine labeled DNA anisotropy assay) and ATP hydrolysis (green fluorescence; phosphate binding protein assay) were simultaneously measured with millisecond timing resolution. The two temporally correlated stopped-flow signals revealed that a preassembled beta. gamma complex composite rapidly binds primer/template DNA in an ATP hydrolysis independent step. Once bound, two molecules of ATP are rapidly hydrolyzed (approximately 34 s(-1)). Following hydrolysis, gamma complex dissociates from the DNA ( approximately 22 s(-1)). Once dissociated, the next cycle of loading is severely compromised, resulting in steady-state ATP hydrolysis rates with a maximum of only approximately 3 s(-1). Two single-site beta dimer interface mutants were examined which had impaired steady-state rates of ATP hydrolysis. The pre-steady-state correlated kinetics of these mutants revealed a pattern essentially identical to wild type. The anisotropy data showed that these mutants decrease the steady-state rates of ATP hydrolysis by causing a buildup of "stuck" binary-ternary complexes on the primer/template DNA.

Base stacking and even/odd behavior of hairpin loops in DNA triplet repeat slippage and expansion with DNA polymerase

Repetitions of CAG or CTG triplets in DNA can form intrastrand hairpin loops with combinations of normal and mismatched base pairs that easily rearrange. Such loops may promote primer-template slippage in DNA replication or repair to give triplet-repeat expansions like those associated with neurodegenerative diseases. Using self-priming sequences (e.g. (CAG)(16)(CTG)(4)), we resolve all hairpin loops formed and measure their slippage and expansion rates with DNA polymerase at 37 degrees C. Comparing CAG/CTG loop structures with GAC/GTC structures, having similar hydrogen bonding but different base stacking, we find that CAG, CTG, and GTC triplets predominantly form even-membered loops that slip in steps of two triplets, whereas GAC triplets favor odd-numbered loops. Slippage rates decline as hairpin stability increases, supporting the idea that slippage initiates more easily in less stable regions. Loop stabilities (in low salt) increase in the order GTC < CAG < GAC < CTG, while slippage rates decrease in the order GTC > CAG approximately GAC > CTG. Loops of GTC compared with CTG melt 9 degrees C lower and slip 6-fold faster. We interpret results in terms of base stacking, by relating melting temperature to standard enthalpy changes for doublets of base pairs and mispairs, considering enthalpy-entropy compensation.

Fidelity of eucaryotic DNA polymerase delta holoenzyme from Schizosaccharomyces pombe

The fidelity of Schizosaccharomyces pombe DNA polymerase delta was measured in the presence or absence of its processivity subunits, proliferating cell nuclear antigen (PCNA) sliding clamp and replication factor C (RFC) clamp-loading complex, using a synthetic 30-mer primer/100-mer template. Synthesis by pol delta alone was distributive. Processive synthesis occurred in the presence of PCNA, RFC, and Escherichia coli single strand DNA-binding protein (SSB) and required the presence of ATP. "Passive" self-loading of PCNA onto DNA takes place in the absence of RFC, in an ATP-independent reaction, which was strongly inhibited by SSB. The nucleotide substitution error rate for pol delta holoenzyme (HE) (pol delta + PCNA + RFC) was 4.6 x 10(-4) for T.G mispairs, 5.3 x 10(-5) for G.G mispairs, and 4.5 x 10(-6) for A.G mispairs. The T.G misincorporation frequency for pol delta without the accessory proteins was unchanged. The fidelity of pol delta HE was between 1 and 2 orders of magnitude lower than that measured for the E. coli pol III HE at the same template position. This relatively low fidelity was caused by inefficient proofreading by the S. pombe polymerase-associated proofreading exonuclease. The S. pombe 3'-exonuclease activity was also extremely inefficient in excising primer-3'-terminal mismatches in the absence of dNTP substrates and in hydrolyzing single-stranded DNA. A comparison of pol delta HE with E. coli pol IIIalpha HE (lacking the proofreading exonuclease subunit) showed that both holoenzymes exhibit similar error rates for each mispair.

Roles of E. coli DNA polymerases IV and V in lesion-targeted and untargeted SOS mutagenesis

The expression of the Escherichia coli DNA polymerases pol V (UmuD'2C complex) and pol IV (DinB) increases in response to DNA damage. The induction of pol V is accompanied by a substantial increase in mutations targeted at DNA template lesions in a process called SOS-induced error-prone repair. Here we show that the common DNA template lesions, TT (6-4) photoproducts, TT cis-syn photodimers and abasic sites, are efficiently bypassed within 30 seconds by pol V in the presence of activated RecA protein (RecA*), single-stranded binding protein (SSB) and pol III's processivity beta,gamma-complex. There is no detectable bypass by either pol IV or pol III on this time scale. A mutagenic 'signature' for pol V is its incorporation of guanine opposite the 3'-thymine of a TT (6-4) photoproduct, in agreement with mutational spectra. In contrast, pol III and pol IV incorporate adenine almost exclusively. When copying undamaged DNA, pol V exhibits low fidelity with error rates of around 10(-3) to 10(-4), with pol IV being 5- to 10-fold more accurate. The effects of RecA protein on pol V, and beta,gamma-complex on pol IV, cause a 15,000- and 3,000-fold increase in DNA synthesis efficiency, respectively. However, both polymerases exhibit low processivity, adding 6 to 8 nucleotides before dissociating. Lesion bypass by pol V does not require beta,gamma-complex in the presence of non-hydrolysable ATPgammaS, indicating that an intact RecA filament may be required for translesion synthesis.

Coping with replication 'train wrecks' in Escherichia coli using Pol V, Pol II and RecA proteins

DNA replication machineries tend to stall when confronted with damaged DNA template sites, causing the biochemical equivalent of a major 'train wreck'. A newly discovered bacterial DNA polymerase, Escherichia coli Pol V, acting in conjunction with the RecA protein, can exchange places with the stalled replicative Pol III core and catalyse 'error-prone' translesion synthesis. In contrast to Pol V-catalysed 'brute-force, sloppier copying', another SOS-induced DNA polymerase, Pol II, plays a pivotal role in an 'error-free', replication-restart DNA repair pathway and probably involves RecA-mediated homologous recombination.

Sloppier copier DNA polymerases involved in genome repair

When chromosomal replication is impeded in the presence of DNA damage, members of a newly discovered UmuC/DinB/Rev1/Rad30 superfamily of procaryotic and eucaryotic DNA polymerases catalyze translesion synthesis at blocked replication forks. Although these polymerases share sequence elements essentially unrelated to the standard replication and repair enzymes, some of them (such as the SOS-induced Escherichia coli pol V) catalyze 'error-prone' translesion synthesis leading to large increases in mutation, whereas others (an example being the Xeroderma pigmentosum variant gene product XPV pol eta) carry out aberrant, yet nonmutagenic translesion synthesis. Ongoing studies of these low fidelity polymerases could provide new insights into the mechanism of somatic hypermutation, a key element in the immune response.

Visualization of two binding sites for the Escherichia coli UmuD'(2)C complex (DNA pol V) on RecA-ssDNA filaments

The heterotrimeric UmuD'(2)C complex of Escherichia coli has recently been shown to possess intrinsic DNA polymerase activity (DNA pol V) that facilitates error-prone translesion DNA synthesis (SOS mutagenesis). When overexpressed in vivo, UmuD'(2)C also inhibits homologous recombination. In both activities, UmuD'(2)C interacts with RecA nucleoprotein filaments. To examine the biochemical and structural basis of these reactions, we have analyzed the ability of the UmuD'(2)C complex to bind to RecA-ssDNA filaments in vitro. As estimated by a gel retardation assay, binding saturates at a stoichiometry of approximately one complex per two RecA monomers. Visualized by cryo-electron microscopy under these conditions, UmuD'(2)C is seen to bind uniformly along the filaments, such that the complexes are completely submerged in the deep helical groove. This mode of binding would impede access to DNA in a RecA filament, thus explaining the ability of UmuD'(2)C to inhibit homologous recombination. At sub-saturating binding, the distribution of UmuD'(2)C complexes along RecA-ssDNA filaments was characterized by immuno-gold labelling with anti-UmuC antibodies. These data revealed preferential binding at filament ends (most likely, at one end). End-specific binding is consistent with genetic models whereby such binding positions the UmuD'(2)C complex (pol V) appropriately for its role in SOS mutagenesis.

The importance of repairing stalled replication forks

The bacterial SOS response to unusual levels of DNA damage has been recognized and studied for several decades. Pathways for re-establishing inactivated replication forks under normal growth conditions have received far less attention. In bacteria growing aerobically in the absence of SOS-inducing conditions, many replication forks encounter DNA damage, leading to inactivation. The pathways for fork reactivation involve the homologous recombination systems, are nonmutagenic, and integrate almost every aspect of DNA metabolism. On a frequency-of-use basis, these pathways represent the main function of bacterial DNA recombination systems, as well as the main function of a number of other enzymatic systems that are associated with replication and site-specific recombination.

A model for Escherichia coli DNA polymerase III holoenzyme assembly at primer/template ends. DNA triggers a change in binding specificity of the gamma complex clamp loader

The gamma complex of the Escherichia coli DNA polymerase III holoenzyme assembles the beta sliding clamp onto DNA in an ATP hydrolysis-driven reaction. Interactions between gamma complex and primer/template DNA are investigated using fluorescence depolarization to measure binding of gamma complex to different DNA substrates under steady-state and presteady-state conditions. Surprisingly, gamma complex has a much higher affinity for single-stranded DNA (K(d) in the nM range) than for a primed template (K(d) in the microM range) under steady-state conditions. However, when examined on a millisecond time scale, we find that gamma complex initially binds very rapidly and with high affinity to primer/template DNA but is converted subsequently to a much lower affinity DNA binding state. Presteady-state data reveals an effective dissociation constant of 1.5 nM for the initial binding of gamma complex to DNA and a dissociation constant of 5.7 microM for the low affinity DNA binding state. Experiments using nonhydrolyzable ATPgammaS show that ATP binding converts gamma complex from a low affinity "inactive" to high affinity "active" DNA binding state while ATP hydrolysis has the reverse effect, thus allowing cycling between active and inactive DNA binding forms at steady-state. We propose that a DNA-triggered switch between active and inactive states of gamma complex provides a two-tiered mechanism enabling gamma complex to recognize primed template sites and load beta, while preventing gamma complex from competing with DNA polymerase III core for binding a newly loaded beta.DNA complex.

Abasic template lesions are strong chain terminators for DNA primase but not for DNA polymerase alpha during the synthesis of new DNA strands

The effects of abasic lesions on both primase activity and DNA polymerase alpha- (pol alpha) catalyzed elongation of primase-synthesized primers were examined. Abasic lesions were strong chain terminators during primer synthesis by primase. However, extension of primase-synthesized primers by pol alpha resulted in 60-93% bypass of abasic lesions. Sequencing of bypass products generated during this primase-coupled pol alpha activity showed that dAMP was preferentially incorporated opposite the abasic lesion, indicating that pol alpha was responsible for bypass. In contrast, previous analyses of pol alpha-catalyzed elongation of exogenously supplied DNA primer-templates showed that abasic lesions strongly terminated DNA synthesis. Thus, elongation of primase-synthesized primers by pol alpha-primase is fundamentally different than elongation of exogenously added primer-templates with respect to interaction with abasic lesions. Furthermore, this high level of abasic lesion bypass during primase-coupled pol alpha activity provides an additional mechanism for how translesional synthesis may occur in vivo, an event hypothesized to be mutagenic.

Division of labor--sequential ATP hydrolysis drives assembly of a DNA polymerase sliding clamp around DNA

The beta sliding clamp encircles DNA and enables processive replication of the Escherichia coli genome by DNA polymerase III holoenzyme. The clamp loader, gamma complex, assembles beta around DNA in an ATP-fueled reaction. Previous studies have shown that gamma complex opens the beta ring and also interacts with DNA on binding ATP. Here, a rapid kinetic analysis demonstrates that gamma complex hydrolyzes two ATP molecules sequentially when placing beta around DNA. The first ATP is hydrolyzed fast, at 25-30 s(-1), while the second ATP hydrolysis is limited to the steady-state rate of 2 s(-1). This step-wise reaction depends on both primed DNA and beta. DNA alone promotes rapid hydrolysis of two ATP molecules, while beta alone permits hydrolysis of only one ATP. These results suggest that beta inserts a slow step between the two ATP hydrolysis events in clamp assembly, during which the clamp loader may perform work on the clamp. Moreover, one ATP hydrolysis is sufficient for release of beta from the gamma complex. This implies that DNA-dependent hydrolysis of the other ATP is coupled to a separate function, perhaps involving work on DNA. A model is presented in which sequential ATP hydrolysis drives distinct events in the clamp-assembly pathway. We also discuss underlying principles of this step-wise mechanism that may apply to the workings of other ATP-fueled biological machines.

A phenotype for enigmatic DNA polymerase II: a pivotal role for pol II in replication restart in UV-irradiated Escherichia coli

DNA synthesis in Escherichia coli is inhibited transiently after UV irradiation. Induced replisome reactivation or "replication restart" occurs shortly thereafter, allowing cells to complete replication of damaged genomes. At the present time, the molecular mechanism underlying replication restart is not understood. DNA polymerase II (pol II), encoded by the dinA (polB) gene, is induced as part of the global SOS response to DNA damage. Here we show that pol II plays a pivotal role in resuming DNA replication in cells exposed to UV irradiation. There is a 50-min delay in replication restart in mutant cells lacking pol II. Although replication restart appears normal in DeltaumuDC strains containing pol II, the restart process is delayed for >90 min in cells lacking both pol II and UmuD'(2)C. Because of the presence of pol II, a transient replication-restart burst is observed in a "quick-stop" temperature-sensitive pol III mutant (dnaE486) at nonpermissive temperature. However, complete recovery of DNA synthesis requires the concerted action of both pol II and pol III. Our data demonstrate that pol II and UmuD'(2)C act in independent pathways of replication restart, thereby providing a phenotype for pol II in the repair of UV-damaged DNA.

UmuD'(2)C is an error-prone DNA polymerase, Escherichia coli pol V

The damage-inducible UmuD' and UmuC proteins are required for most SOS mutagenesis in Escherichia coli. Our recent assay to reconstitute this process in vitro, using a native UmuD'(2)C complex, revealed that the highly purified preparation contained DNA polymerase activity. Here we eliminate the possibility that this activity is caused by a contaminating DNA polymerase and show that it is intrinsic to UmuD'(2)C. E. coli dinB has recently been shown to have DNA polymerase activity (pol IV). We suggest that UmuD'(2)C, the fifth DNA polymerase discovered in E. coli, be designated as E. coli pol V. In the presence of RecA, beta sliding clamp, gamma clamp loading complex, and E. coli single-stranded binding protein (SSB), pol V's polymerase activity is highly "error prone" at both damaged and undamaged DNA template sites, catalyzing efficient bypass of abasic lesions that would otherwise severely inhibit replication by pol III holoenzyme complex (HE). Pol V bypasses a site-directed abasic lesion with an efficiency about 100- to 150-fold higher than pol III HE. In accordance with the "A-rule," dAMP is preferentially incorporated opposite the lesion. A pol V mutant, UmuD'(2)C104 (D101N), has no measurable lesion bypass activity. A kinetic analysis shows that addition of increasing amounts of pol III to a fixed level of pol V inhibits lesion bypass, demonstrating that both enzymes compete for free 3'-OH template-primer ends. We show, however, that despite competition for primer-3'-ends, pol V and pol III HE can nevertheless interact synergistically to stimulate synthesis downstream from a template lesion.

"Action-at-a-distance" mutagenesis. 8-oxo-7, 8-dihydro-2'-deoxyguanosine causes base substitution errors at neighboring template sites when copied by DNA polymerase beta

8-Oxo-7,8-dihydro-2'-deoxyguanosine (8-oxo-dG), a common oxidative DNA lesion, favors a syn-conformation in DNA, enabling formation of stable 8-oxo-dG.A base mispairs resulting in G.C --> T.A transversion mutations. When human DNA polymerase (pol) beta was used to copy a short single-stranded gap containing a site-directed 8-oxo-dG lesion, incorporation of dAMP opposite 8-oxo-dG was slightly favored over dCMP depending on "downstream" sequence context. Unexpectedly, however, a significant increase in dCMP.A and dGMP.A mispairs was also observed at the "upstream" 3'-template site adjacent to the lesion. Errors at these undamaged template sites occurred in four sequence contexts with both gapped and primed single-stranded DNA templates, but not when pol alpha replaced pol beta. Error rates at sites adjacent to 8-oxo-dG were roughly 1% of the values opposite 8-oxo-dG, potentially generating tandem mutations during in vivo short-gap repair synthesis by pol beta. When 8-oxo-dG was replaced with 8-bromo-2'-deoxyguanosine, incorporation of dCMP was strongly favored by both enzymes, with no detectable misincorporation occurring at neighboring template sites.

A sticker-based model for DNA computation

We introduce a new model of molecular computation that we call the sticker model. Like many previous proposals it makes use of DNA strands as the physical substrate in which information is represented and of separation by hybridization as a central mechanism. However, unlike previous models, the stickers model has a random access memory that requires no strand extension and uses no enzymes; also (at least in theory), its materials are reusable. The paper describes computation under the stickers model and discusses possible means for physically implementing each operation. Finally, we go on to propose a specific machine architecture for implementing the stickers model as a microprocessor-controlled parallel robotic workstation. In the course of this development a number of previous general concerns about molecular computation (Smith, 1996; Hartmanis, 1995; Linial et al., 1995) are addressed. First, it is clear that general-purpose algorithms can be implemented by DNA-based computers, potentially solving a wide class of search problems. Second, we find that there are challenging problems, for which only modest volumes of DNA should suffice. Third, we demonstrate that the formation and breaking of covalent bonds is not intrinsic to DNA-based computation. Fourth, we show that a single essential biotechnology, sequence-specific separation, suffices for constructing a general-purpose molecular computer. Concerns about errors in this separation operation and means to reduce them are addressed elsewhere (Karp et al., 1995; Roweis and Winfree, 1999). Despite these encouraging theoretical advances, we emphasize that substantial engineering challenges remain at almost all stages and that the ultimate success or failure of DNA computing will certainly depend on whether these challenges can be met in laboratory investigations.