Prevalence of the mismatch-repair-deficient phenotype in colonic adenomas arising in HNPCC patients: results of a 5-year follow-up study

In hereditary nonpolyposis colorectal cancer (HNPCC) syndrome, more than 90% of the carcinomas show microsatellite instability (MSI) due to a loss of mismatch repair (MMR) function. Although adenomas are very common in HNPCC and demonstrate an accelerated adenoma-carcinoma sequence, data about the prevalence and development of MSI in these early neoplastic lesions are lacking. To determine whether MSI and loss of MMR-protein expression are already present in early stages of tumorigenesis and could therefore be used as a screening tool to identify HNPCC patients before they develop an invasive carcinoma, we analyzed 71 adenomas of 36 HNPCC patients during a 5-year follow-up study. These 36 patients were part of a cohort of 122 HNPCC patients who were investigated at the Institute of Pathology, Klinikum Kassel, as part of the multicentric German HNPCC Consortium, which currently serves more than 2,880 registered families. The diagnosis of HNPCC was based either on the detection of a pathogenic germline mutation in the MSH2, MLH1, or MSH6 genes or in cases where a pathogenic mutation was not found; diagnosis of HNPCC was made, because all patients fulfilled the Amsterdam or Bethesda criteria and revealed a high degree of MSI (MSI-H) as well as loss of one of the MMR proteins by IHC in the cancer tissue. We found that most adenomas (58/71) were MSI-H and had loss of MMR-protein expression. Of the 71 adenomas, 3 were MSI-H with expression of all MMR proteins, and 3 out of 71 displayed loss of a MMR protein with the microsatellites being classified as microsatellite stable (MSS). However, 7 of the 31 adenomas that were located more than 5 cm away from the carcinoma revealed an MSS status (n=6) or low in MSI (n=1) and expressed all MMR proteins. In summary, a significant percentage of HNPCC-associated adenomas (7/31, 22.6%) developing at a distance of more than 5 cm from the corresponding carcinoma did not show the MSI-H MMR-deficient phenotype and expressed all MMR genes. To our knowledge, this is the first study that shows that in most HNPCC patients, the mutator pathway is already detectable in adenomas, but MMR-proficient adenomas can also be found. Therefore, screening for MMR deficiency should not be applied routinely in adenomas with the goal to identify HNPCC patients.

An improved gel-based DNA microarray method for detecting single nucleotide mismatch

3-D polyacrylamide gel-based DNA microarray platforms provide a high capacity for nucleic acids immobilization and a solution-mimicking environment for hybridization. However, several technological bottlenecks still remain in these platforms, such as difficult microarray preparation and high fluorescent background, which limit their application. In this study, two new approaches have been developed to improve the convenience in microarray preparation and to reduce the background after hybridization. To control the polymerization process, solutions containing acrylamide-modified oligonucleotide, acrylamide, glycerol and ammonium persulfate are spotted onto a functionalized glass slide, and then the slide is transferred to a vacuum chamber with TEMED, so that TEMED is vaporized and diffused into the spots to induce polymerization. By applying an electric field across a hybridized microarray to remove the nonspecifically bound labeled targets, this approach can solve the problem of high fluorescent background of the gel-based microarray after hybridization. Experimental results show that our immobilization method can be used to construct high quality microarrays and exhibits good reproducibility. Moreover, the polymerization is not affected by PCR medium, so that PCR products can be used for microarray construction without being treated by commercial purification cartridges. Electrophoresis can improve the signal-to-noise significantly and has the ability to differentiate single nucleotide variation between two homozygotes and a heterozygote. Our results demonstrated that this is a reliable novel method for high-throughput mutation analysis and disease diagnosis.

Microsatellite Instability in Nasopharyngeal and Lymphoepithelial Carcinomas of the Head and Neck

Lymphoepithelial carcinoma (LEC) is a descriptive diagnosis for an undifferentiated carcinoma that has a typical morphologic appearance of large vesicular cells with prominent nucleoli and infiltrating lymphocytes. Tumors with this histopathologic appearance in the head and neck can be categorized as either those that occur in endemic areas, such as Southeast Asia and are associated with Epstein-Barr virus (EBV) infection, or those that occur in other countries and are less commonly associated with EBV. The molecular changes in endemic EBV-related LEC have been fairly well studied and include both alterations in tumor suppressor genes and 1 report of high levels of microsatellite instability. In nonendemic LECs arising in western countries, there is very little data related to molecular mutational profiles. In this study, we examined 19 cases of LEC from the United States for evidence of microsatellite instability at the DNA level and for alterations in the DNA mismatch repair (MMR) system at the immunohistochemical staining level. Only 3/19 cases showed high-level microsatellite instability and only 1 of these showed an alteration in the DNA MMR protein expression hMLH1. These data suggest that alterations in DNA MMR system are not a common mechanism of tumorigenesis in LEC of the head and neck in a nonendemic country.

[MYH and colorectal cancer. A significant advance?]

Colorectal cancer is the second most common neoplasm and the second most frequent cause of cancer-related deaths in Spain. This neoplasm has an important genetic component, although relatively few of the genes involved in its hereditary or familial forms have been identified. One of the latest genes to be identified is the MYH gene. Colorectal polyposis associated with mutations in the MYH gene is an autosomal recessive syndrome characterized by the development of colorectal adenomas and cancer. It is the first disease predisposing to cancer to be associated with defects in base excision repair.

Germline mutations of the hMLH1 and hMSH2 mismatch repair genes in Belgian hereditary nonpolyposis colon cancer (HNPCC) patients

BACKGROUND

Hereditary nonpolyposis colon cancer (HNPCC-Lynch syndrome) is caused by mutations in genes involved in DNA mismatch repair (MMR), mostly in the hMLH1 and hMSH2 genes. The mutation spectrum in the Belgian population is still poorly documented.

AIM

To report our experience on the mutation screening in Belgian familial colorectal cancer (CRC) patients, including the investigation of the pathogenicity of the missense and splice mutations. To increase the mutation detection rate by selecting the target population.

METHODS

Two hundred and twenty five Belgian patients with familial clustering of CRC were genetically tested. Point mutations in the hMLH1 and hMSH2 genes were screened by denaturing gradient gel electrophoresis (DGGE) followed by direct sequencing. Genomic deletions and duplications were assessed by multiplex ligase dependent probe amplification (MLPA) and multiplex PCR. Missense mutations were examined for pathogenicity by means of cosegregation of the mutation with the disease, microsatellite instability (MSI) in tumors, immunohistochemical staining of tumors and determination of the population frequency of the particular mutation.

RESULTS

Twenty five pathogenic mutations were identified from which 16 were novel: 7 frameshifts, one in frame deletion, 5 genomic deletions, 5 splice defects, 4 nonsense (stop) mutations and 3 missense mutations which were classified as pathogenic (out of 10 missense mutations). In retrospect, a mutation detection rate of 71% was obtained if MSI was used as a supplementary selection criterion in addition to familial clustering.

CONCLUSION

Different types of pathogenic mutations in the hMLH1 and hMSH2 genes were identified in a Belgian CRC group with familial clustering. The mutation detection yield drastically increased by preliminar selection of those familial CRC patients with a microsatellite instable tumor. Considerable attention went to the assessment of the pathogenicity of the missense mutations. In practice, the cosegregation with the disease was the most relevant criterion.

A method to select for mutator DNA polymerase deltas in Saccharomyces cerevisiae

Proofreading DNA polymerases share common short peptide motifs that bind Mg(2+) in the exonuclease active center; however, hydrolysis rates are not the same for all of the enzymes, which indicates that there are functional and likely structural differences outside of the conserved residues. Since structural information is available for only a few proofreading DNA polymerases, we developed a genetic selection method to identify mutant alleles of the POL3 gene in Saccharomyces cerevisiae, which encode DNA polymerase delta mutants that replicate DNA with reduced fidelity. The selection procedure is based on genetic methods used to identify "mutator" DNA polymerases in bacteriophage T4. New yeast DNA polymerase delta mutants were identified, but some mutants expected from studies of the phage T4 DNA polymerase were not detected. This would indicate that there may be important differences in the proofreading pathways catalyzed by the two DNA polymerases.

Accumulation of recessive lethal mutations in Saccharomyces cerevisiae mlh1 mismatch repair mutants is not associated with gross chromosomal rearrangements

We examined mismatch repair (MMR)-defective diploid strains of budding yeast grown for approximately 160 generations to determine whether decreases in spore viability due to the uncovering of recessive lethal mutations correlated with an increase in gross chromosomal rearrangements (GCRs). No GCRs were detected despite dramatic decreases in spore viability, suggesting that frameshift and/or other unrepaired DNA replication lesions play a greater role than chromosomal instability in decreasing viability in MMR-defective strains.

Identification and survival of carriers of mutations in DNA mismatch-repair genes in colon cancer

BACKGROUND

The identification of mutations in germ-line DNA mismatch-repair genes at the time of diagnosis of colorectal cancer is important in the management of the disease.

METHODS

Without preselection and regardless of family history, we recruited 870 patients under the age of 55 years soon after they received a diagnosis of colorectal cancer. We studied these patients for germ-line mutations in the DNA mismatch-repair genes MLH1, MSH2, and MSH6 and developed a two-stage model by multivariate logistic regression for the prediction of the presence of mutations in these genes. Stage 1 of the model incorporated only clinical variables; stage 2 comprised analysis of the tumor by immunohistochemical staining and tests for microsatellite instability. The model was validated in an independent population of patients. We analyzed 2938 patient-years of follow-up to determine whether genotype influenced survival.

RESULTS

There were 38 mutations among the 870 participants (4 percent): 15 mutations in MLH1, 16 in MSH2, and 7 in MSH6. Carrier frequencies in men (6 percent) and women (3 percent) differed significantly (P<0.04). The addition of immunohistochemical analysis in stage 2 of the model had a sensitivity of 62 percent and a positive predictive value of 80 percent. There were 35 mutations in the validation series of 155 patients (23 percent): 19 mutations in MLH1, 13 in MSH2, and 3 in MSH6. The performance of the model was robust among a wide range of cutoff probabilities and was superior to that of the Bethesda and Amsterdam criteria for hereditary nonpolyposis colorectal cancer. Survival among carriers was not significantly different from that among noncarriers.

CONCLUSIONS

We devised and validated a method of identifying patients with colorectal cancer who are carriers of mutations in DNA repair genes. Survival was similar among carriers and noncarriers.

Accelerated growth of intestinal tumours after radiation exposure in Mlh1-knockout mice: evaluation of the late effect of radiation on a mouse model of HNPCC

Mlh1-knockout mice have been developed as a useful model of hereditary non-polyposis colorectal cancer (HNPCC). In this study, we analyzed the pathology of gastrointestinal tumours (GIT) in these mice in detail and examined the possible effects of ionizing radiation on the induction of intestinal tumours to evaluate the late response to radiotherapy in HNPCC. Mlh1-/- mice spontaneously developed GIT and thymic lymphomas by 48 weeks. GIT included not only well differentiated adenocarcinomas but also poorly differentiated and mucinous adenocarcinomas, suggesting that this mouse is a good model for HNPCC. In contrast to colon cancers from HNPCC patients, however, carcinomas of Mlh1-/- mice expressed p53 and showed a lack of transforming growth factor (TGF)-betaRII mutation, which resulted in the expression of TGF-betaRII protein. Irradiation of 10-week-old Mlh1-/- mice accelerated GIT development but had little effect at 2 weeks. Mlh1+/- and Mlh1+/+ mice were not susceptible to spontaneous or radiation-induced thymic lymphomas and GIT until 72 weeks after birth. The development and pathology of GIT in Mlh1-/- mice suggest that this mouse is a good model for HNPCC, although tumour-related responsible genes might be different from HNPCC. As X-ray exposure promoted carcinogenesis of GIT in adult Mlh1-/- mice, an increased risk of secondary cancers after radiotherapy for HNPCC patients should be taken into consideration.

Mechanism of instability in abortive cycling by T7 RNA polymerase

Abortive transcription, the premature release of short transcripts 2-8 bases in length, is a unique feature of transcription, accompanying the transition from initiation to elongation in all RNA polymerases. The current study focuses on major factors that relate to the stability of initially transcribing abortive complexes in T7 RNA polymerase. Building on previous studies, results reveal that collapse of the DNA from the downstream end of the bubble is a major contributor to the characteristic instability of abortive complexes. Furthermore, transcription from a novel DNA construct containing a nick between positions -14 and -13 of the nontemplate strand suggests that the more flexible promoter reduces somewhat the strain inherent in initially transcribing complexes, with a resulting decrease in abortive product release. Finally, as assessed by exonuclease III footprinting and transcription profiles, a DNA construct defective in bubble collapse specifically from the downstream end exhibits less abortive cycling and little perturbation of the final transition to elongation, including the process of promoter release.

Involvement of ERCC1/XPF and XPG in oligodeoxynucleotide-directed gene modification

Oligodeoxynucleotide (ODN)-mediated gene alteration was postulated to occur in two steps, DNA strand pairing and DNA repair. Once alignment has occurred through homologous strand pairing, a single mismatch is formed between an oligonucleotide and one of the target strands. Because of this mismatch, it has been suggested that proteins involved in a mismatch repair pathway (MMR) participate in the process. We proposed an alternative model, in which a transient assimilation of ODN to the target DNA can interrupt the trafficking of RNA polymerase, and the stalled RNA polymerase may signal for recruitment of DNA repair proteins, including transcription-coupled (TCR) DNA repair and nucleotide excision repair (NER) pathways. Recently, we found that transcription of many genes participating in NER and MMR was induced by the presence of plasmid DNA, and the extent of induction correlated with episomal gene repair rates. To investigate whether an increased level of induction of genes involved in specific DNA repair pathways has a functional role in ODN-directed gene repair, we performed episomal targeting in several cell lines with a specific defective gene in NER and MMR pathways. Comparison among several genetically related cell lines harboring a specific defective gene and complementation of missing activities showed that a primary pathway for gene correction involves some of the proteins participating in NER, primarily two endonucleases processing a DNA lesion, but not MMR.

A distinct TthMutY bifunctional glycosylase that hydrolyzes not only adenine but also thymine opposite 8-oxoguanine in the hyperthermophilic bacterium, Thermus thermophilus

Oxidative damage represents a major threat to genomic stability because the major product of DNA oxidation, 8-oxoguanine (GO), frequently mispairs with adenine during replication. We were interested in finding out how hyperthermophilic bacteria under goes the process of excising mispaired adenine from A/GO to deal with genomic oxidative damage. Herein we report the properties of an Escherichia coli MutY (EcMutY) homolog, TthMutY, derived from a hyperthermophile Thermus thermophilus. TthMutY preferentially excises on A/GO and G/GO mispairs and has additional activities on T/GO and A/G mismatches. TthMutY has significant sequence homology to the A/G and T/G mismatch recognition motifs, respectively, of MutY and Mig.MthI. A substitution from Tyr112 to Ser or Ala (Y112S and Y112A) in the putative thymine-binding site of TthMutY showed significant decrease in DNA glycosylase activity. A mutant form of TthMutY, R134K, could form a Schiff base with DNA and fully retained its DNA glycosylase activity against A/GO and A/G mispair. Interestingly, although TthMutY cannot form a trapped complex with substrate in the presence of NaBH(4), it expressed AP lyase activity, suggesting Tyr112 in TthMutY may be the key residue for AP lyase activity. These results suggest that TthMutY may be an example of a novel class of bifunctional A/GO mismatch DNA glycosylase that can also remove thymine from T/GO mispair.

Microsatellite instability in multiple nonfamilial malignancies

Development of multiple tumors of different histopathologic types may suggest a profound generalized genetic defect, such as malfunction of DNA mismatch repair (MMR) mechanism. Defects in this mechanism are best reflected in microsatellite instability (MSI). We aimed to determine the role of MSI in a group of patients with dual malignancies and compared the data with that of patients with a single malignancy. Fifty patients were enrolled in the study, of whom 16 patients developed both solid and hematologic nonfamilial malignancies, 18 patients developed a single matched hematologic malignancy, and 16 a single matched solid malignancy. Five microsatellite markers were replicated by polymerase chain reaction (PCR) after DNA extraction from paraffin-embedded tissue blocks and analyzed by the GeneScan Analysis Software. The MSI-high phenotype was defined as instability in at least 40% of the examined loci. A higher prevalence of MSI-high phenotype was found in patients with dual malignancies (31.3%) compared with patients with single hematologic (5.6%) or solid malignancy (6.3%) (P = 0.0498 and 0.07, respectively). In conclusion, defects in DNA MMR mechanism may have an important role in the development of multiple sporadic nonfamilial malignancies.

Mismatched siRNAs downregulate mRNAs as a function of target site location

In mammalian cells, RNA interference can be mediated by synthetic duplex RNAs, termed small interfering RNAs (siRNAs), which assist in cleaving completely complementary mRNA transcripts. MicroRNAs (miRNAs) are endogenous small RNAs that assist in translationally repressing mRNAs with regions of partial complementarity, but may also reduce transcript levels. Since miRNAs predominantly interact with the 3' UTRs of transcripts, we sought to ask if mismatched siRNAs mimicking miRNAs affect cognate mRNA levels as a function of target site location. We find that mismatched siRNAs targeting the 3' UTRs of two endogenous transcripts yield a greater reduction in mRNA levels than those targeting the coding region. Our findings demonstrate the importance of target site location within endogenous mRNAs for small RNAs associated with RNAi.

The multifaceted mismatch-repair system

By removing biosynthetic errors from newly synthesized DNA, mismatch repair (MMR) improves the fidelity of DNA replication by several orders of magnitude. Loss of MMR brings about a mutator phenotype, which causes a predisposition to cancer. But MMR status also affects meiotic and mitotic recombination, DNA-damage signalling, apoptosis and cell-type-specific processes such as class-switch recombination, somatic hypermutation and triplet-repeat expansion. This article reviews our current understanding of this multifaceted DNA-repair system in human cells.

Prospective evaluation of fluorouracil chemotherapy based on the genetic makeup of colorectal cancer

Evaluation of 5‐fluorouracil chemotherapy and survival, based on mismatch repair (MMR) status, indicates that patients with MMR proficient colorectal tumours benefit from 5‐fluorouracil treatment while patients with MMR deficient tumours do not

Mismatch repair status in the prediction of benefit from adjuvant fluorouracil chemotherapy in colorectal cancer

AIM

Some retrospective studies have shown a lack of benefit of 5-fluorouracil (5-FU) adjuvant chemotherapy in patients with mismatch repair (MMR) deficient colorectal cancer. Our aim was to assess if this molecular marker can predict benefit from 5-FU adjuvant chemotherapy. A second objective was to determine if MMR status influences short term survival.

METHODS

We included 754 patients with a median follow up of 728.5 days (range 1-1097). A total of 260 patients with stage II or III tumours received 5-FU adjuvant chemotherapy, according to standard clinical criteria and irrespective of their MMR status. A tumour was considered MMR deficient when either BAT-26 showed instability or there was loss of MLH1 or MSH2 protein expression.

RESULTS

At the end of the follow up period, 206 patients died and 120 presented with tumour recurrence. Sixty six (8.8%) patients had MMR deficient tumours. There were no significant differences in overall survival (MMR competent 72.1%; MMR deficient 78.8%; p = 0.3) or disease free survival (MMR competent 61.3%; MMR deficient 72.3%; p = 0.08). In patients with stage II and III tumours, benefit from 5-FU adjuvant chemotherapy was restricted to patients with MMR competent tumours (overall survival: chemotherapy 87.1%; non-chemotherapy 73.5%; log rank, p = 0.00001). Patients with MMR deficient tumours did not benefit from adjuvant chemotherapy (overall survival: chemotherapy 89.5%; non-chemotherapy 82.4%; log rank, p = 0.4).

CONCLUSIONS

Benefit from 5-FU adjuvant chemotherapy depends on the MMR status of tumours in patients with colorectal cancer. 5-FU adjuvant chemotherapy improves survival in patients with MMR competent tumours but this benefit from chemotherapy cannot be extended to patients with MMR deficient tumours.

Desmoid-type fibromatoses involving the brachial plexus: treatment options and assessment of c-KIT mutational status

OBJECT

Desmoid-type fibromatoses are a locally invasive soft-tissue lesion that is most commonly encountered in abdominal sites. The tumor also affects head and neck areas, particularly the supraclavicular region, where it may encase and distort the brachial plexus and compromise neurovascular structures. Neurosurgeons may be called on to treat desmoid-type fibromatoses in these sites. The authors describe their experience in treating four patients with desmoid-type fibromatoses involving the brachial plexus and report the results of immunohistochemical analysis of the tumors.

METHODS

Gross-total excision with nerve sparing was the first-line therapy of choice, although the surgery was challenging. Intraoperative identification of the site of tumor origin from musculoaponeurotic tissues by the neurosurgeon was necessary in two of the four cases to achieve a correct frozen section or final pathological diagnosis. Immunostaining for c-KIT (CD117) was undertaken in all cases in light of a previous report of positive CD117 immunoreactivity in abdominal desmoid-type fibromatoses. All four tumors manifested weak focal immunostaining for c-KIT. One of the patients was given adjuvant imatinib mesylate therapy, with limited success. Subsequent polymerase chain reaction testing revealed that three of the four tumors manifested a single base pair change in exon 10 of the c-KIT gene (A to C in two cases and A to G in one case). There was local recurrence in three patients, despite gross-total excision. With the combination of surgery and radiation therapy, local disease control was achieved in three of the four patients.

CONCLUSIONS

This represents the first report of c-KIT sequencing in desmoid-type fibromatoses and suggests a possible biological basis for continuing to explore the use of adjuvant imatinib mesylate therapy.

Regulation of replication protein A functions in DNA mismatch repair by phosphorylation

Replication protein A (RPA) is involved in multiple stages of DNA mismatch repair (MMR); however, the modulation of its functions between different stages is unknown. We show here that phosphorylation likely modulates RPA functions during MMR. Unphosphorylated RPA initially binds to nicked heteroduplex DNA to facilitate assembly of the MMR initiation complex. The unphosphorylated protein preferentially stimulates mismatch-provoked excision, possibly by cooperatively binding to the resultant single-stranded DNA gap. The DNA-bound RPA begins to be phosphorylated after extensive excision, resulting in severalfold reduction in the DNA binding affinity of RPA. Thus, during the phase of repair DNA synthesis, the phosphorylated RPA readily disassociates from DNA, making the DNA template available for DNA polymerase delta-catalyzed resynthesis. These observations support a model of how phosphorylation alters the DNA binding affinity of RPA to fulfill its differential requirement at the various stages of MMR.

Adaptive mutations in Salmonella typhimurium phenotypic of purR super-repression

Under non-lethal selective conditions, a non-dividing or very slowly dividing microbial population gives rise to mutations that relieve selective pressures. This process is described as adaptive mutation. Salmonella typhimurium strain 5-28 has been used as a system for studying adaptive mutations in the chromosomal regulatory gene purR and its target, the purD operator. When this strain is plated on a minimal lactose medium, no apparent growth of parent lawn is observed, yet the revertant colonies accumulate over a period of time. Analysis of the purR mutational spectra showed that the frequencies of transitions and transversions were not significantly different among the growth-dependent and adaptive mutations. But the frequencies for five kinds of -1 frameshifts were significantly different between the growth-dependent and adaptive types. Among the growth-dependent mutations, most one-base deletions occurred in non-iterated bases and were distributed randomly. Among adaptive mutations, the frequency of one-base deletions in small mononucleotide repeats was higher and mutations were concentrated at three hotspots. One-base deletion in small mononucleotide repeats are generally believed to result from DNA polymerase slippage errors, which are not corrected by DNA repair machinery. We further investigated the role of DNA repair on adaptive mutation. Our results showed that the mismatch repair (MMR) might function less efficiently during adaptive mutation. However, DNA oxidative damage repair seemed no less effective in correcting errors under selective pressures than during non-selective growth.

Optimization of unnatural base pair packing for polymerase recognition

As part of an effort to expand the genetic alphabet, we have been examining the ability of predominately hydrophobic nucleobase analogues to pair in duplex DNA and during polymerase-mediated replication. We previously reported the synthesis and thermal stability of unnatural base pairs formed between nucleotides bearing simple methyl-substituted phenyl ring nucleobase analogues. Several of these pairs are virtually as stable and selective as natural base pairs in the same sequence context. Here, we report the characterization of polymerase-mediated replication of the same unnatural base pairs. We find that every facet of replication, including correct and incorrect base pair synthesis, as well as continued primer extension beyond the unnatural base pair, is sensitive to the specific methyl substitution pattern of the nucleobase analogue. The results demonstrate that neither hydrogen bonding nor large aromatic surface area is required for polymerase recognition, and that interstrand interactions between small aromatic rings may be optimized for replication. Combined with our previous results, these studies suggest that appropriately derivatized phenyl nucleobase analogues represent a promising approach toward developing a third base pair and expanding the genetic alphabet.

Origins of sequence selectivity in homologous genetic recombination: insights from rapid kinetic probing of RecA-mediated DNA strand exchange

Despite intense effort over the past 30 years, the molecular determinants of sequence selectivity in RecA-mediated homologous recombination have remained elusive. Here, we describe when and how sequence homology is recognized between DNA strands during recombination in the context of a kinetic model for RecA-mediated DNA strand exchange. We characterized the transient intermediates of the reaction using pre-steady-state kinetic analysis of strand exchange using oligonucleotide substrates containing a single fluorescent G analog. We observed that the reaction system was sensitive to heterology between the DNA substrates; however, such a "heterology effect" was not manifest when functional groups were added to or removed from the edges of the base-pairs facing the minor groove of the substrate duplex. Hence, RecA-mediated recombination must occur without the involvement of a triple helix, even as a transient intermediate in the process. The fastest detectable reaction phase was accelerated when the structure or stability of the substrate duplex was perturbed by internal mismatches or the replacement of G.C by I.C base-pairs. These findings indicate that the sequence specificity in recombination is achieved by Watson-Crick pairing in the context of base-pair dynamics inherent to the extended DNA structure bound by RecA during strand exchange.

The ribosome's response to codon-anticodon mismatches

The ribosome is a molecular machine that synthesizes polypeptides from aminoacyl-tRNAs according to the sequence of the mRNA template. Codon reading by the anticodon of tRNA is controlled by a network of ribosome contacts that are specific for each position of the codon-anticodon duplex and involve A-minor RNA interactions. Rapid and accurate tRNA selection is accomplished by switching the conformation of the decoding site between accepting and rejecting mode, regardless of the thermodynamic stability of the respective codon-anticodon complexes or their interactions at the decoding site. The forward reactions are particularly sensitive to mismatches and determine the variations in the extent of misreading of near-cognate codons, both during initial selection and proofreading. This review emphasizes the progress made in understanding the mechanisms that determine recognition and selection of tRNA by the translational machinery.