Antigen Selection for Enhanced Affinity T-Cell Receptor-Based Cancer Therapies.

Evidence of adaptive immune responses in the prevention of cancer has been accumulating for decades. Spontaneous T-cell responses occur in multiple indications, bringing the study of de novo expressed cancer antigens to the fore and highlighting their potential as targets for cancer immunotherapy. Circumventing the immune-suppressive mechanisms that maintain tumor tolerance and driving an antitumor cytotoxic T-cell response in cancer patients may eradicate the tumor or block disease progression. Multiple strategies are being pursued to harness the cytotoxic potential of T cells clinically. Highly promising results are now emerging. The focus of this review is the target discovery process for cancer immune therapeutics based on affinity-matured T-cell receptors (TCRs). Target cancer antigens in the context of adoptive cell transfer technologies and soluble biologic agents are discussed. To appreciate the impact of TCR-based technology and understand the TCR discovery process, it is necessary to understand key differences between TCR-based therapy and other immunotherapy approaches. The review first summarizes key advances in the cancer immunotherapy field and then discusses the opportunities that TCR technology provides. The nature and breadth of molecular targets that are tractable to this approach are discussed, together with the challenges associated with finding them.

Efficient cleavage of single and clustered AP site lesions within mono-nucleosome templates by CHO-K1 nuclear extract contrasts with retardation of incision by purified APE1.

Clustered DNA damage is a unique characteristic of radiation-induced DNA damage and the formation of these sites poses a serious challenge to the cell's repair machinery. Within a cell DNA is compacted, with nucleosomes being the first order of higher level structure. However, few data are reported on the efficiency of clustered-lesion processing within nucleosomal DNA templates. Here, we show retardation of cleavage of a single AP site by purified APE1 when contained in nucleosomal DNA, compared to cleavage of an AP site in non-nucleosomal DNA. This retardation seen in nucleosomal DNA was alleviated by incubation with CHO-K1 nuclear extract. When clustered DNA damage sites containing bistranded AP sites were present in nucleosomal DNA, efficient cleavage of the AP sites was observed after treatment with nuclear extract. The resultant DSB formation led to DNA dissociating from the histone core and nucleosomal dispersion. Clustered damaged sites containing bistranded AP site/8-oxoG residues showed no retardation of cleavage of the AP site but retardation of 8-oxoG excision, compared to isolated lesions, thus DSB formation was not seen. An increased understanding of processing of clustered DNA damage in a nucleosomal environment may lead to new strategies to enhance the cytotoxic effects of radiotherapeutics.

Effects of (5'S)-5',8-cyclo-2'-deoxyadenosine on the base excision repair of oxidatively generated clustered DNA damage. A biochemical and theoretical study.

The presence of 5',8-cyclo-2'-deoxyadenosine (5'S)-cdA induces modifications in the geometry of the DNA duplex in the 5'-end direction of the strand and in the 3'-end direction of the complementary strand. As a consequence, the enzymes are probably not able to adjust their active sites in this rigid structure. Additionally, clustered DNA damage sites, a signature of ionising radiation, pose a severe challenge to a cell's repair machinery, particularly base excision repair (BER). To date, clusters containing a DNA base lesion, (5'S)-cdA, which is repaired by nucleotide excision repair, have not been explored. We have therefore investigated whether bistranded clusters containing (5'S)-cdA influence the repairability of an opposed AP site lesion, which is repaired by BER. Using synthetic oligonucleotides containing a bistranded cluster with (5'S)-cdA and an AP site at different interlesion separations, we have shown that in the presence of (5'S)-cdA on the 5'-end side, repair of the AP site by the BER machinery is retarded when the AP site is ≤8 bases from the (5'S)-cdA. However, if (5'S)-cdA is located on the 3'-end side with respect to the AP site, the effect on its repair is much weaker and totally disappears for distances ≥8 bases.

Increased mutability and decreased repairability of a three-lesion clustered DNA-damaged site comprised of an AP site and bi-stranded 8-oxoG lesions.

PURPOSE: Ionizing radiation induces DNA damage, some of which are present in clusters, defined as two or more lesions within one to two helical turns of DNA by passage of a single radiation track. These clusters are thought to contribute to the detrimental effects of radiation, in part due to the compromised repair of clustered DNA damaged sites. MATERIALS AND METHODS: The repair of three-lesion cluster present in oligonucleotides were determined in vitro using the hamster cell line CHO-K1 nuclear extract or purified proteins involved in base excision repair. The mutagenic potential of these clusters present in a plasmid was determined using an Escherichia coli reporter assay. RESULTS: We have shown that the repair of an abasic (AP) site within a three-lesion cluster, comprised of an AP site and bi-stranded 8-oxo-7,8-dihydroguanine (8-oxoG) lesions, is retarded compared to that of an isolated AP site in an in vitro base excision repair (BER) assay. Further, the mutation frequency of the clustered damaged site is up to three times greater than that of an isolated 8-oxoG lesion. CONCLUSIONS: As a consequence of enhanced mutagenic potential of clusters, non-double-strand break (DSB) DNA damage may contribute to the detrimental effects of radiation, in addition to the effects of DSB.

Reduced repair capacity of a DNA clustered damage site comprised of 8-oxo-7,8-dihydro-2'-deoxyguanosine and 2-deoxyribonolactone results in an increased mutagenic potential of these lesions.

A signature of ionizing radiation is the induction of DNA clustered damaged sites. Non-double strand break (DSB) clustered damage has been shown to compromise the base excision repair pathway, extending the lifetimes of the lesions within the cluster, compared to isolated lesions. This increases the likelihood the lesions persist to replication and thus increasing the mutagenic potential of the lesions within the cluster. Lesions formed by ionizing radiation include 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodGuo) and 2-deoxyribonolactone (dL). dL poses an additional challenge to the cell as it is not repaired by the short-patch base excision repair pathway. Here we show recalcitrant dL repair is reflected in mutations observed when DNA containing it and a proximal 8-oxodGuo is replicated in Escherichia coli. 8-oxodGuo in close proximity to dL on the opposing DNA strand results in an enhanced frequency of mutation of the lesions within the cluster and a 20 base sequence flanking the clustered damage site in an E. coli based plasmid assay. In vitro repair of a dL lesion is reduced when compared to the repair of an abasic (AP) site and a tetrahydrofuran (THF), and this is due mainly to a reduction in the activity of polymerase ß, leading to retarded FEN1 and ligase 1 activities. This study has given insights in to the biological effects of clusters containing dL.

Delayed repair of radiation induced clustered DNA damage: friend or foe?

A signature of ionizing radiation exposure is the induction of DNA clustered damaged sites, defined as two or more lesions within one to two helical turns of DNA by passage of a single radiation track. Clustered damage is made up of double strand breaks (DSB) with associated base lesions or abasic (AP) sites, and non-DSB clusters comprised of base lesions, AP sites and single strand breaks. This review will concentrate on the experimental findings of the processing of non-DSB clustered damaged sites. It has been shown that non-DSB clustered damaged sites compromise the base excision repair pathway leading to the lifetime extension of the lesions within the cluster, compared to isolated lesions, thus the likelihood that the lesions persist to replication and induce mutation is increased. In addition certain non-DSB clustered damaged sites are processed within the cell to form additional DSB. The use of E. coli to demonstrate that clustering of DNA lesions is the major cause of the detrimental consequences of ionizing radiation is also discussed. The delayed repair of non-DSB clustered damaged sites in humans can be seen as a "friend", leading to cell killing in tumour cells or as a "foe", resulting in the formation of mutations and genetic instability in normal tissue.

Hierarchy of lesion processing governs the repair, double-strand break formation and mutability of three-lesion clustered DNA damage.

Ionising radiation induces clustered DNA damage sites which pose a severe challenge to the cell's repair machinery, particularly base excision repair. To date, most studies have focussed on two-lesion clusters. We have designed synthetic oligonucleotides to give a variety of three-lesion clusters containing abasic sites and 8-oxo-7, 8-dihydroguanine to investigate if the hierarchy of lesion processing dictates whether the cluster is cytotoxic or mutagenic. Clusters containing two tandem 8-oxoG lesions opposing an AP site showed retardation of repair of the AP site with nuclear extract and an elevated mutation frequency after transformation into wild-type or mutY Escherichia coli. Clusters containing bistranded AP sites with a vicinal 8-oxoG form DSBs with nuclear extract, as confirmed in vivo by transformation into wild-type E. coli. Using ung1 E. coli, we propose that DSBs arise via lesion processing rather than stalled replication in cycling cells. This study provides evidence that it is not only the prompt formation of DSBs that has implications on cell survival but also the conversion of non-DSB clusters into DSBs during processing and attempted repair. The inaccurate repair of such clusters has biological significance due to the ultimate risk of tumourigenesis or as potential cytotoxic lesions in tumour cells.

5,6-Dihydrothymine impairs the base excision repair pathway of a closely opposed AP site or single-strand break.

Ionizing radiation can induce clustered DNA damage (two or more lesions formed within one to two helical turns of DNA by passage of a single ionization track). Using oligonucleotide constructs containing clustered DNA lesions at defined positions, evidence is presented demonstrating that a persistent 5,6-dihydrothymine (DHT) lesion reduces the efficiency of rejoining, in mammalian nuclear extracts, of an opposing AP site or SSB when within 5 bp. The efficiency of repair of the SSB is reduced when DHT is present on the opposing strand in both the 3' and 5' orientation; however, the efficiency of the repair of the AP site is reduced only when DHT is present 3' to the AP site. DNA polymerase beta and ligation are particularly impaired by DHT. It was also shown that in the presence of DHT there is a greater dependence on the long-patch base excision repair pathway than when DHT is absent. In addition, immunodepletion of XRCC1 from the nuclear extracts slows down the initial rate of repair of the AP site in both the presence and absence of DHT, but immunodepletion of XRCC1 has no influence on the repair of an SSB.

Interplay of two major repair pathways in the processing of complex double-strand DNA breaks.

Radiation-induced complex double-strand breaks (DSBs) characterised by base lesions, abasic sites or single-strand breaks in close proximity to the break termini, are believed to be a major cause of the biological effects of ionising radiation exposure. It has been hypothesised that complex DSBs pose problems for the repair machinery of the cell. Using a biochemical approach, we have investigated the challenge to two major repair processes: base excision repair and ligation of DSB ends. Double-stranded oligonucleotides were synthesised with 8-oxo-7,8-dihydroguanine (8-oxoG) at defined positions relative to readily ligatable 3'-hydroxy or 5'-phosphate termini. The break termini interfere with removal of 8-oxoG during base excision repair as elucidated from the severely reduced efficiency of 8-oxoG removal by OGG1 with AP endonuclease-1 when in close proximity to break termini. NEIL-1, however, can partially restore processing of complex DSBs in an AP endonuclease-1 independent manner. The influence of 8-oxoG on ligation shows delayed rejoining if 8-oxoG is positioned two to three bases from the 3'-hydroxy or six bases from the 5'-phosphate termini. When two 8-oxoG lesions are positioned across the break junction ligation is severely retarded. This reduced efficiency of repair indicates that complex DSBs are likely to persist longer than simple DSBs in cells, and as a consequence are more significant in contributing to the biological effects of ionising radiation.

Base excision repair processing of abasic site/single-strand break lesions within clustered damage sites associated with XRCC1 deficiency.

Ionizing radiation induces clustered DNA damage, which presents a challenge to the cellular repair machinery. The repair efficiency of a single-strand break (SSB) is approximately 4x less than that for repair of an abasic (AP) site when in a bistranded cluster containing 8-oxoG. To explore whether this difference in repair efficiency involves XRCC1 or other BER proteins, synthetic oligonucleotides containing either an AP site or HAP1-induced SSB (HAP1-SSB) 1 or 5 bp 5' or 3' to 8-oxoG on the opposite strand were synthesized and the repair investigated using either nuclear extracts from hamster cells proficient (AA8) or deficient (EM7) in XRCC1 or purified BER proteins. XRCC1 is important for efficient processing of an AP site in clustered damage containing 8-oxoG but does not affect the already low repair efficiency of a SSB. Ligase I partly compensates for the absence of the XRCC1/ligaseIII during short-patch BER of an AP site when in a cluster but only weakly if at all for a HAP1-SSB. The major difference between the repair of an AP site and a HAP1-SSB when in a 8-oxoG containing cluster is the greater efficiency of short-patch BER with the AP site compared with that for a HAP1-SSB.

An AP site can protect against the mutagenic potential of 8-oxoG when present within a tandem clustered site in E. coli.

Ionizing radiation induces clustered DNA damaged sites, defined as two or more lesions formed within one or two helical turns of the DNA through passage of a single radiation track. It is now established that clustered DNA damage sites are found in cells and present a challenge to the repair machinery of the cell but to date, most studies have investigated the effects of bi-stranded lesions. A subset of clustered DNA damaged sites exist in which two or more lesions are present in tandem on the same DNA strand. In this study synthetic oligonucleotides containing an AP site 1, 3 or 5 bases 5' or 3' to 8-oxo-7,8-dihydroguanine (8-oxoG) on the same DNA strand were synthesized as a model of a tandem clustered damaged sites. It was found that 8-oxoG retards the incision of the AP site by exonuclease III (Xth) and formamidopyrimidine DNA glycosylase (Fpg). In addition the rejoining of the AP site by xrs5 nuclear extracts is impaired by the presence of 8-oxoG. The mutation frequency arising from 8-oxoG within a tandem clustered site was determined in both wild type and mutant E. coli backgrounds. In wild-type, nth, fpg and mutY null E. coli, the mutation frequency is slightly elevated when an AP site is in tandem to 8-oxoG, compared with when 8-oxoG is present as a single lesion. Interestingly, in the double mutant mutY/fpg null E. coli, the mutation frequency of 8-oxoG is reduced when an AP site is present in tandem compared with when 8-oxoG is present as a single lesion. This study demonstrates that tandem lesions can present a challenge to the repair machinery of the cell.

8-OxoA inhibits the incision of an AP site by the DNA glycosylases Fpg, Nth and the AP endonuclease HAP1.

Ionizing radiation induces clustered DNA damage sites, whereby two or more individual DNA lesions are formed within one or two helical turns of DNA by a single radiation track. A subset of DNA clustered damage sites exist in which the lesions are located in tandem on the same DNA strand. Recent studies have established that two closely opposed lesions impair the repair machinery of the cell, but few studies have investigated the processing of tandem lesions. In this study, synthetic double-stranded oligonucleotides were synthesized to contain 8-oxoA and an AP site in tandem, separated by up to four bases in either a 5' or 3' orientation. The influence 8-oxoA has on the incision of the AP site by the E. coli glycosylases Fpg and Nth protein and the human AP endonuclease HAP1 was assessed. 8-OxoA has little or no effect on the efficiency of incision of the AP site by Nth protein; however, the efficiency of incision of the AP site by Fpg protein is reduced in the presence of 8-oxoA even up to a four-base separation in both the 5' and 3' orientations. 8-OxoA influences the efficiency of HAP1 incision of the AP site only when it is 3' to the AP site and separated by up to two bases. This study demonstrates that the initial stages of base excision repair can be impaired by the presence of a second base lesion in proximity to an AP site on the same DNA strand. This impairment could have biological consequences, such as mutation induction, if the AP site is present at replication.

Efficiency of repair of an abasic site within DNA clustered damage sites by mammalian cell nuclear extracts.

Ionizing radiation induces clustered DNA damage sites which have been shown to challenge the repair mechanism(s) of the cell. Evidence demonstrating that base excision repair is compromised during the repair of an abasic (AP) site present within a clustered damage site is presented. Simple bistranded clustered damage sites, comprised of either an AP-site and 8-oxoG or two AP-sites, one or five bases 3' or 5' to each other, were synthesized in oligonucleotides, and repair was carried out in xrs5 nuclear extracts. The rate of repair of an AP-site when present opposite 8-oxoG is reduced by up to 2-fold relative to that when an AP-site is present as an isolated lesion. The mechanism of repair of the AP-site shows asymmetry, depending on its position relative to 8-oxoG on the opposite strand. The AP-site is rejoined by short-patch base excision repair when the lesions are 5' to each other, whereas when the lesions are 3' to one another, rejoining of the AP-site occurs by both long-patch and short-patch repair processes. The major stalling of repair occurs at the DNA ligase step. 8-OxoG and an AP-site present within a cluster are processed sequentially, limiting the formation of double-strand breaks to <4%. In contrast, when two AP-sites are contained within the clustered DNA damage site, both AP-sites are incised simultaneously, giving rise to double-strand breaks. This study provides new insight into understanding the processes that lead to the biological consequences of radiation-induced DNA damage and ultimately tumorigenesis.

8-OxoG retards the activity of the ligase III/XRCC1 complex during the repair of a single-strand break, when present within a clustered DNA damage site.

Ionising radiation produces clustered DNA damage. Recent studies have established that the efficiency of excision of a lesion within clustered damage sites is reduced. This study presents evidence that the repair of clustered DNA damage is compromised, relative to that of the isolated lesions, since the lifetime of both lesions is extended by up to eight fold. Simple clustered damage sites, comprised of a single-strand break, one or five bases 3' or 5' to 8-oxoG on the opposite strand, were synthesised in oligonucleotides and repair carried out in XRS5 nuclear extracts. The rate of repair of the single-strand break within these clustered damage sites is reduced, mainly due to inhibition of the DNA ligase III/XRCC1 complex. The single-strand break, present as an isolated lesion, is repaired by short-patch base excision repair, however the mechanism of repair of the single-strand break within the clustered damage site is asymmetric. When the lesions are 5' to each other, the single-strand break is rejoined by short-patch repair whereas the rejoining of the single-strand break occurs by long-patch type repair when the lesions are 3' to one another. The retardation of DNA ligase III/XRCC1 complex, following addition of one base, is responsible for the initiation of long-patch base excision repair when the lesions are 3' to each other. The lesions within the cluster are processed sequentially, the single-strand break being repaired before excision of 8-oxoG, limiting the formation of double-strand breaks to <2%. Stalled processing of clustered DNA damage is suggested to have implications for mutation induction by radiation.