The multi-specific VH-based Humabody CB213 co-targets PD1 and LAG3 on T cells to promote anti-tumour activity.

BACKGROUND: Improving cancer immunotherapy long-term clinical benefit is a major priority. It has become apparent that multiple axes of immune suppression restrain the capacity of T cells to provide anti-tumour activity including signalling through PD1/PD-L1 and LAG3/MHC-II. METHODS: CB213 has been developed as a fully human PD1/LAG3 co-targeting multi-specific Humabody composed of linked VH domains that avidly bind and block PD1 and LAG3 on dual-positive T cells. We present the preclinical primary pharmacology of CB213: biochemistry, cell-based function vs. immune-suppressive targets, induction of T cell proliferation ex vivo using blood obtained from NSCLC patients, and syngeneic mouse model anti-tumour activity. CB213 pharmacokinetics was assessed in cynomolgus macaques. RESULTS: CB213 shows picomolar avidity when simultaneously engaging PD1 and LAG3. Assessing LAG3/MHC-II or PD1/PD-L1 suppression individually, CB213 preferentially counters the LAG3 axis. CB213 showed superior activity vs. αPD1 antibody to induce ex vivo NSCLC patient T cell proliferation and to suppress tumour growth in a syngeneic mouse tumour model, for which both experimental systems possess PD1 and LAG3 suppressive components. Non-human primate PK of CB213 suggests weekly clinical administration. CONCLUSIONS: CB213 is poised to enter clinical development and, through intercepting both PD1 and LAG3 resistance mechanisms, may benefit patients with tumours escaping front-line immunological control.

Diverse human VH antibody fragments with bio-therapeutic properties from the Crescendo Mouse.

We describe the 'Crescendo Mouse', a human VH transgenic platform combining an engineered heavy chain locus with diverse human heavy chain V, D and J genes, a modified mouse Cγ1 gene and complete 3' regulatory region, in a triple knock-out (TKO) mouse background devoid of endogenous immunoglobulin expression. The addition of the engineered heavy chain locus to the TKO mouse restored B cell development, giving rise to functional B cells that responded to immunization with a diverse response that comprised entirely 'heavy chain only' antibodies. Heavy chain variable (VH) domain libraries were rapidly mined using phage display technology, yielding diverse high-affinity human VH that had undergone somatic hypermutation, lacked aggregation and showed enhanced expression in E. coli. The Crescendo Mouse produces human VH fragments, or Humabody® VH, with excellent bio-therapeutic potential, as exemplified here by the generation of antagonistic Humabody® VH specific for human IL17A and IL17RA.

Nucleosome remodeling at origins of global genome-nucleotide excision repair occurs at the boundaries of higher-order chromatin structure.

Repair of UV-induced DNA damage requires chromatin remodeling. How repair is initiated in chromatin remains largely unknown. We recently demonstrated that global genome-nucleotide excision repair (GG-NER) in chromatin is organized into domains in relation to open reading frames. Here, we define these domains, identifying the genomic locations from which repair is initiated. By examining DNA damage-induced changes in the linear structure of nucleosomes at these sites, we demonstrate how chromatin remodeling is initiated during GG-NER. In undamaged cells, we show that the GG-NER complex occupies chromatin, establishing the nucleosome structure at these genomic locations, which we refer to as GG-NER complex binding sites (GCBSs). We demonstrate that these sites are frequently located at genomic boundaries that delineate chromosomally interacting domains (CIDs). These boundaries define domains of higher-order nucleosome-nucleosome interaction. We demonstrate that initiation of GG-NER in chromatin is accompanied by the disruption of dynamic nucleosomes that flank GCBSs by the GG-NER complex.

Integrated Microarray-based Tools for Detection of Genomic DNA Damage and Repair Mechanisms.

The genetic information contained within the DNA molecule is highly susceptible to chemical and physical insult, caused by both endogenous and exogenous sources that can generate in the order of thousands of lesions a day in each of our cells (Lindahl, Nature 362(6422):709-715, 1993). DNA damages interfere with DNA metabolic processes such as transcription and replication and can be potent inhibitors of cell division and gene expression. To combat these regular threats to genome stability, a host of DNA repair mechanisms have evolved. When DNA lesions are left unrepaired due to defects in the repair pathway, mutations can arise that may alter the genetic information of the cell. DNA repair is thus fundamental to genome stability and defects in all the major repair pathways can lead to cancer predisposition. Therefore, the ability to accurately measure DNA damage at a genomic scale and determine the level, position, and rates of removal by DNA repair can contribute greatly to our understanding of how DNA repair in chromatin is organized throughout the genome. For this reason, we developed the 3D-DIP-Chip protocol described in this chapter. Conducting such measurements has potential applications in a variety of other fields, such as genotoxicity testing and cancer treatment using DNA damage inducing chemotherapy. Being able to detect and measure genomic DNA damage and repair patterns in individuals following treatment with chemotherapy could enable personalized medicine by predicting response to therapy.

Global genome nucleotide excision repair is organized into domains that promote efficient DNA repair in chromatin.

The rates at which lesions are removed by DNA repair can vary widely throughout the genome, with important implications for genomic stability. To study this, we measured the distribution of nucleotide excision repair (NER) rates for UV-induced lesions throughout the budding yeast genome. By plotting these repair rates in relation to genes and their associated flanking sequences, we reveal that, in normal cells, genomic repair rates display a distinctive pattern, suggesting that DNA repair is highly organized within the genome. Furthermore, by comparing genome-wide DNA repair rates in wild-type cells and cells defective in the global genome-NER (GG-NER) subpathway, we establish how this alters the distribution of NER rates throughout the genome. We also examined the genomic locations of GG-NER factor binding to chromatin before and after UV irradiation, revealing that GG-NER is organized and initiated from specific genomic locations. At these sites, chromatin occupancy of the histone acetyl-transferase Gcn5 is controlled by the GG-NER complex, which regulates histone H3 acetylation and chromatin structure, thereby promoting efficient DNA repair of UV-induced lesions. Chromatin remodeling during the GG-NER process is therefore organized into these genomic domains. Importantly, loss of Gcn5 significantly alters the genomic distribution of NER rates; this has implications for the effects of chromatin modifiers on the distribution of mutations that arise throughout the genome.

Sandcastle: software for revealing latent information in multiple experimental ChIP-chip datasets via a novel normalisation procedure.

ChIP-chip is a microarray based technology for determining the genomic locations of chromatin bound factors of interest, such as proteins. Standard ChIP-chip analyses employ peak detection methodologies to generate lists of genomic binding sites. No previously published method exists to enable comparative analyses of enrichment levels derived from datasets examining different experimental conditions. This restricts the use of the technology to binary comparisons of presence or absence of features between datasets. Here we present the R package Sandcastle ­ Software for the Analysis and Normalisation of Data from ChIP-chip AssayS of Two or more Linked Experiments ­ which allows for comparative analyses of data from multiple experiments by normalising all datasets to a common background. Relative changes in binding levels between experimental datasets can thus be determined, enabling the extraction of latent information from ChIP-chip experiments. Novel enrichment detection and peak calling algorithms are also presented, with a range of graphical tools, which facilitate these analyses. The software and documentation are available for download from http://reedlab.cardiff.ac.uk/sandcastle.

How chromatin is remodelled during DNA repair of UV-induced DNA damage in Saccharomyces cerevisiae.

Global genome nucleotide excision repair removes DNA damage from transcriptionally silent regions of the genome. Relatively little is known about the molecular events that initiate and regulate this process in the context of chromatin. We've shown that, in response to UV radiation-induced DNA damage, increased histone H3 acetylation at lysine 9 and 14 correlates with changes in chromatin structure, and these alterations are associated with efficient global genome nucleotide excision repair in yeast. These changes depend on the presence of the Rad16 protein. Remarkably, constitutive hyperacetylation of histone H3 can suppress the requirement for Rad7 and Rad16, two components of a global genome repair complex, during repair. This reveals the connection between histone H3 acetylation and DNA repair. Here, we investigate how chromatin structure is modified following UV irradiation to facilitate DNA repair in yeast. Using a combination of chromatin immunoprecipitation to measure histone acetylation levels, histone acetylase occupancy in chromatin, MNase digestion, or restriction enzyme endonuclease accessibility assays to analyse chromatin structure, and finally nucleotide excision repair assays to examine DNA repair, we demonstrate that global genome nucleotide excision repair drives UV-induced chromatin remodelling by controlling histone H3 acetylation levels in chromatin. The concerted action of the ATPase and C3HC4 RING domains of Rad16 combine to regulate the occupancy of the histone acetyl transferase Gcn5 on chromatin in response to UV damage. We conclude that the global genome repair complex in yeast regulates UV-induced histone H3 acetylation by controlling the accessibility of the histone acetyl transferase Gcn5 in chromatin. The resultant changes in histone H3 acetylation promote chromatin remodelling necessary for efficient repair of DNA damage. Recent evidence suggests that GCN5 plays a role in NER in human cells. Our work provides important insight into how GG-NER operates in chromatin.

A novel method for the genome-wide high resolution analysis of DNA damage.

DNA damage occurs via endogenous and exogenous genotoxic agents and compromises a genome's integrity. Knowing where damage occurs within a genome is crucial to understanding the repair mechanisms which protect this integrity. This paper describes a new development based on microarray technology which uses ultraviolet light induced DNA damage as a paradigm to determine the position and frequency of DNA damage and its subsequent repair throughout the entire yeast genome.

A role for checkpoint kinase-dependent Rad26 phosphorylation in transcription-coupled DNA repair in Saccharomyces cerevisiae.

Upon DNA damage, eukaryotic cells activate a conserved signal transduction cascade known as the DNA damage checkpoint (DDC). We investigated the influence of DDC kinases on nucleotide excision repair (NER) in Saccharomyces cerevisiae and found that repair of both strands of an active gene is affected by Mec1 but not by the downstream checkpoint kinases, Rad53 and Chk1. Repair of the nontranscribed strand (by global genome repair) requires new protein synthesis, possibly reflecting the involvement of Mec1 in the activation of repair genes. In contrast, repair of the transcribed strand by transcription-coupled NER (TC-NER) occurs in the absence of new protein synthesis, and DNA damage results in Mec1-dependent but Rad53-, Chk1-, Tel1-, and Dun1-independent phosphorylation of the TC-NER factor Rad26, a member of the Swi/Snf group of ATP-dependent translocases and yeast homologue of Cockayne syndrome B. Mutation of the Rad26 phosphorylation site results in a decrease in the rate of TC-NER, pointing to direct activation of Rad26 by Mec1 kinase. These findings establish a direct role for Mec1 kinase in transcription-coupled repair, at least partly via phosphorylation of Rad26, the main transcription-repair coupling factor.

Lux ex tenebris: nucleotide resolution DNA repair and nucleosome mapping.

In recent years a great deal of progress has been made in understanding how the various DNA repair mechanisms function when DNA is assembled into chromatin. In the case of nucleotide excision repair, a core group of DNA repair proteins is required in vitro to observe DNA repair activity in damaged DNA devoid of chromatin structure. This group of proteins is not sufficient to promote repair in the same DNA when assembled into nucleosomes; the first level of chromatin compaction. Clearly other factors are required for efficient DNA repair of chromatin. For some time chromatin has been considered a barrier to be overcome, and inhibitory to DNA metabolic processes including DNA repair. However, an emerging picture suggests a fascinating link at the interface of chromatin metabolism and DNA repair. In this view these two fundamental processes are mechanistically intertwined and function in concert to bring about regulated DNA repair throughout the genome. Light from the darkness has come as a result of many elegant studies performed by a number of research groups. Here we describe two techniques developed in our laboratories which we hope have contributed to our understanding in this arena.

Tilting at windmills? The nucleotide excision repair of chromosomal DNA.

A typical view of how DNA repair functions in chromatin usually depicts a struggle in which the DNA repair machinery battles to overcome the inhibitory effect of chromatin on the repair process. It may be that in this current interpretation the repair mechanisms are 'tilting at windmills', fighting an imaginary foe. An emerging picture suggests that we should not consider chromatin as an inhibitory force to be overcome like some quixotic giant by the DNA repair processes. Instead we should now recognize that DNA repair and chromatin metabolism are inextricably and mechanistically linked. Here we discuss the latest findings which are beginning to reveal how changes in chromatin dynamics integrate with the DNA repair process in response to UV induced DNA damage, with an emphasis on events in the yeast Saccharomyces cerevisiae.

Complementary roles of yeast Rad4p and Rad34p in nucleotide excision repair of active and inactive rRNA gene chromatin.

Nucleotide excision repair (NER) removes a plethora of DNA lesions. It is performed by a large multisubunit protein complex that finds and repairs damaged DNA in different chromatin contexts and nuclear domains. The nucleolus is the most transcriptionally active domain, and in yeast, transcription-coupled NER occurs in RNA polymerase I-transcribed genes (rDNA). Here we have analyzed the roles of two members of the xeroderma pigmentosum group C family of proteins, Rad4p and Rad34p, during NER in the active and inactive rDNA. We report that Rad4p is essential for repair in the intergenic spacer, the inactive rDNA coding region, and for strand-specific repair at the transcription initiation site, whereas Rad34p is not. Rad34p is necessary for transcription-coupled NER that starts about 40 nucleotides downstream of the transcription initiation site of the active rDNA, whereas Rad4p is not. Thus, although Rad4p and Rad34p share sequence homology, their roles in NER in the rDNA locus are almost entirely distinct and complementary. These results provide evidences that transcription-coupled NER and global genome NER participate in the removal of UV-induced DNA lesions from the transcribed strand of active rDNA. Furthermore, nonnucleosome rDNA is repaired faster than nucleosome rDNA, indicating that an open chromatin structure facilitates NER in vivo.

Chromatin modifications and nucleotide excision repair.

We have developed an innovative approach to examine the incidence and frequency of repair of UV-induced cyclobutane pyrimidine dimers at nucleotide resolution in yeast sequences of choice and have then adapted it for the footprinting of nucleosomes and regulatory proteins that bind to DNA. Using the mating-type-specific gene MFA2 as a model, we have determined DNA repair rates for individual DNA lesions throughout the sequence. Positioned nucleosomes occur when the gene is repressed and we have begun to unravel how they are modified after UV. This radiation triggers histone acetylation, primarily at H3, and is mediated by the Gcn5 histone acetyltransferase; its absence reduces repair substantially. UV also triggers chromatin remodelling as measured by increased accessibility of restriction sites at the cores of the two nucleosomes in the gene's upstream control region; this is partly mediated by Swi2, a yeast SWI/SNF factor. Surprisingly neither of these events require functional NER, but NER is needed to return the chromatin to its pre-UV state.

Saccharomyces cerevisiae Rad16 mediates ultraviolet-dependent histone H3 acetylation required for efficient global genome nucleotide-excision repair.

In yeast, global genome nucleotide-excision repair (GG-NER) requires a protein complex containing Rad7 and Rad16. Rad16 is a member of the switch/sucrose nonfermentable superfamily, and it is presumed that chromatin remodelling is its primary function during repair. We show that RAD16 is required for ultraviolet-dependent hyperacetylation of histone H3 (Lys 9 and Lys 14) at the MFA2 promoter and throughout the genome. The yeast repressor complex Ssn6-Tup1 represses many genes including MFA2. TUP1 deletion results in constitutive hyperacetylation of histone H3, nucleosome disruption and derepression of gene transcription in Tup1-regulated genes. GG-NER in the MFA2 promoter proceeds more rapidly in tup1Delta alpha-cells compared with wild type, even when transcription is inhibited. We show that elevated histone H3 acetylation levels in the MFA2 promoter in tup1Delta alpha-cells result in Rad7- and Rad16-independent GG-NER, and that Rad16 mediates the ultraviolet-induced acetylation of histone H3, necessary for efficient GG-NER.

Histone acetylation, chromatin remodelling, transcription and nucleotide excision repair in S. cerevisiae: studies with two model genes.

We describe the technology and two model systems in yeast designed to study nucleotide excision repair (NER) in relation to transcription and chromatin modifications. We employed the MFA2 and MET16 genes as models. How transcription-coupled (TCR) and global genome repair (GGR) operate at the transcriptionally active and/or repressed S. cerevisiae MFA2 locus, and how this relates to nucleosome positioning are considered. We discuss the role of the Gcn5p histone acetyltransferase, also associated with MFA2's transcriptional activation, in facilitating efficient NER at the transcriptionally active and inactive genes. The effect of Gcn5p's absence in reducing NER was local and UV stimulates Gcn5p-mediated histone acetylation at the repressed MFA2 promoter. After UV irradiation Swi2p is partly responsible for facilitating access to restriction of DNA in the cores of the nucleosomes at the MFA2 promoter. The data suggest similarities between chromatin remodelling for NER and transcription, yet differences must exist to ensure this gene remains repressed in alpha cells during NER. For MET16, we consider experiments examining chromatin structure, transcription and repair in wild type and cbf1Delta cells under repressing or derepressing conditions. Cbf1p is a sequence specific DNA binding protein required for MET16 chromatin remodelling and transcription.

UV irradiation stimulates histone acetylation and chromatin remodeling at a repressed yeast locus.

Chromatin immunoprecipitation with anti-acetyl histone H3 (K9 and K14) and anti-acetyl histone H4 (K5, K8, K12, and K16) antibodies shows that Lys-9 and/or Lys-14 of histone H3, but not the relevant sites of histone H4 in nucleosomes at the repressed MFA2 promoter, are hyperacetylated after UV irradiation. This level of histone hyperacetylation diminishes gradually as repair proceeds. Accompanying this, chromatin in the promoter becomes more accessible to restriction enzymes after UV irradiation and returns to the pre-UV state gradually. UV-related histone hyperacetylation and chromatin remodeling in the MFA2 promoter depend on Gcn5p and partially on Swi2p, respectively. Deletion of GCN5, but not of SWI2, impairs repair of DNA damage in the MFA2 promoter. The post-UV histone modifications and chromatin remodeling at the repressed MFA2 promoter do not activate MFA2 transcriptionally, nor do they require damage recognition by Rad4p or Rad14p. Furthermore, we show that UV irradiation triggers genome-wide histone hyperacetylation at both histone H3 and H4. These experiments indicate that chromatin at a yeast repressed locus undergoes active change after UV radiation treatment and that failure to achieve histone H3 hyperacetylation impairs the repair of DNA damage.

The Saccharomyces cerevisiae histone acetyltransferase Gcn5 has a role in the photoreactivation and nucleotide excision repair of UV-induced cyclobutane pyrimidine dimers in the MFA2 gene.

How DNA repair enzymes or complexes gain access to chromatin is still not understood. Here, we have studied the role of the S. cerevisiae histone acetyltransferase Gcn5 in photoreactivation (PR) and nucleotide excision repair (NER) at the level of the genome, the MFA2 and RPB2 genes, and at specific nucleotides within MFA2. The deletion of GCN5 markedly reduced the PR and NER of UV-induced cyclobutane pyrimidine dimers in MFA2 but much less so in RPB2, whereas no detectable defect was seen for repair of the genome overall. In Delta(gcn5), the MFA2 mRNA level is reduced by fourfold, while transcription from RPB2 is reduced only to 80 %. These changes in transcription correlate with the changes in NER and PR found in the Delta(gcn5) mutant. However, changes in MFA2 transcription cannot account for the decrease in NER in the non-transcribed strand and the control region of MFA2 where global genome repair (GGR) operates. We conclude that the histone acetyltransferase Gcn5 influences PR and NER at MFA2 in both its transcribed and non-transcribed DNA, yet it has little effect on these processes for most of the yeast genome. As a result, we speculate that histone acetylation allows efficient access of the repair machinery to chromosomal DNA damages either indirectly via influencing transcription or directly via modifying chromatin structure irrespective of transcription.