Kingsley G , Skagia A , Passaretti P , Fernandez-Cuesta C , Reynolds-Winczura A , Koscielniak K , Gambus A .

Medical Research Council , BB/T001860/1 Biotechnology and Biological Sciences Research Council , 215510/Z/19/Z Wellcome Trust , Wellcome Trust

             DNA strand elongation involved in DNA replication
             MCM complex
             cell division
             cyclin-dependent protein kinase activity

	Graphical Abstract
	Figure 1. DONSON interacts with replisome on replicating chromatin in Xenopus laevis egg extract. (A) Model of eukaryotic DNA replication. S. cerevisiae initiation factors are listed with human homologues names in brackets. (B) DNA replication was set up in Xenopus egg extract and synthesis of nascent DNA followed by incorporation of α32P-dATP into newly synthesised DNA (left). At the same indicated times chromatin was isolated and chromatin bound factors resolved on SDS-PAGE and immunoblotted with indicated antibodies (right). ‘No DNA’ control served as chromatin specificity control, while Coomassie stained histones from the bottom of the gel serve as a loading and purity control. (C) Replication reaction was set up in egg extract in optional presence of indicated replication initiation inhibitors. Chromatin fractions were isolated in the middle of S-phase and analysed by immunoblotting as in (B). (D) Chromatin replicating in egg extract was isolated in the middle of S-phase, chromatin bound protein complexes were released from chromatin by digestion of DNA with benzonase and replisomes immunoprecipitated using α-Cdc45 or α-GINS specific antibodies. Non-specific commercial IgG antibodies served as non-specific control. Input and immunoprecipitated samples were resolved on SDS-PAGE and immunoblotted with indicated antibodies. (E) Chromatin was prepared as in (D), but immunoprecipitation was carried out with α-DONSON antibody. (F) Replication reaction was set up in egg extract and treated optionally with indicated replication stress and DNA damaging agents. Chromatin was isolated after 60 min of reaction progression (middle/late stage of replication) and immunoblotted with indicated antibodies as in (B) (right), while the ability of the extract to synthesise nascent DNA was assessed after 90 min of replication reaction progression (left). (G) Replication reaction was set up in egg extract and optionally supplemented with aphidicolin and caffeine, as indicated. Progression of DNA synthesis during replication reaction was analysed (left), while chromatin bound factors were analysed by immunoblotting as in (B) (right). (H) Chromatin replicating in egg extract in optional presence of aphidicolin and caffeine was isolated, chromatin protein complexes released by DNA digestion and Cdc45 or GINS immunoprecipitated as in (D).
	Figure 2. DONSON is essential for DNA replication in X.laevis egg extract. (A, B) Xenopus egg extract was immunodepleted of DONSON using either rabbit α-DONSON antibodies (A) or sheep α-DONSON antibodies (B). Nonspecific rabbit or sheep commercial IgGs were used for control IgG– depletions. The efficiency of depletion was established by immunoblotting in comparison to titration of original extract (left). The ability of immunodepleted extracts to synthesise nascent DNA was analysed by incorporation of α32P-dATP into newly synthesised DNA (middle). Mean of n = 5 for rabbit DONSON depletion, n = 3 for sheep DONSON depletion is presented with SEM. The binding of replication fork factors in the absence of DONSON was analysed by immunoblotting of isolated chromatin fractions as in Figure 1B (right). (C) Replication reaction was set up in IgG- or DONSON-depleted extracts with optional addition of recombinant wt DONSON. The level of nascent DNA synthesis was followed as above (left top, n = 3, Mean with SEM is presented) and chromatin was isolated at indicated times and analysed by immunoblotting with indicated antibodies as in (A) (right). Quantification of fold change of chromatin bound Cdc45 and Psf2 at the peak of replication in IgG- and DONSON-depleted extract with optional addition of rDONSON over n = 3. The levels were normalised to level in IgG-depleted extract. Mean with SEM (left, bottom).
	Figure 3. DONSON is essential for replication initiation in egg extract. (A) Replication reaction was set up in IgG- or DONSON-depleted egg extract optionally supplemented with caffeine. DNA synthesis was analysed throughout the reaction by incorporation of α32P-dATP into newly synthesised DNA (left) and chromatin bound factors analysed at indicated times with indicated antibodies (right). (B) Egg extract was immunodepleted of DONSON with rabbit antibodies as in Figure 2A, chromatin was isolated in the middle of S-phase (45 min) and whole chromatin proteome of IgG- and DONSON-depleted reaction analysed by mass spectrometry. The total spectral count of selected replication factors is presented. (C) Replication reaction was set up in IgG- or DONSON-depleted egg extract and chromatin isolated at indicated times. Chromatin bound factors were analysed by immunoblotting with indicated antibodies as in Figure 1B. (D) Replication reaction was set up in Xenopus egg extract, chromatin isolated at indicated times during early stages of replication reaction and analysed as above. (E) Replication reaction was set up in egg extract in optional presence of indicated replication initiation inhibitors. Chromatin fractions were isolated in the middle of S-phase and analysed by immunoblotting as in (A).
	Figure 4. DONSON interacts with replication initiation factors. (A) Chromatin replication reaction was carried on in presence of aphidicolin and caffeine. Chromatin was isolated after 60 min of replication reaction, protein complexes were released from chromatin by digestion of DNA with benzonase and non-specific control antibodies or α-DONSON(s) antibodies used for immunoprecipitation. The input and immunoprecipitated samples were analysed by immunoblotting with indicated antibodies. (B) As (A) but α-TopBP1 or α-Treslin antibodies were used for immunoprecipitation. (C) DNA replication reaction was set up in egg extract with optional addition of replication initiation inhibitors (p27KIP1 or Cdc7i). In the middle of S-phase, replicating nuclei were isolated in a buffer without detergent, which allows to retain part of the nucleoplasm. From this input material, DONSON was immunoprecipitated and immunoprecipitation samples analysed by immunoblotting with indicated antibodies. As a control, non-specific antibody immunoprecipitation from unchallenged S-phase input was performed in parallel. (D) TopBP1 was immunodepleted from egg extract to 25% of the original level. Replication reaction was set up in IgG- and TopBP1-depleted extract and chromatin isolated at indicated times of reaction and chromatin fractions analysed as above.
	Figure 5. DONSON 3D structure organisation. (A) AlphaFold prediction of DONSON 3D structure. High confidence prediction in blue, low confidence prediction in yellow/orange. (B, C) Based on the predicted structure DONSON can be divided into six domains—N-terminal D1 domain which is unstructured, structured D2, flexible loop D3, structured D4 and D6 with a short turn motif D5. The 1D model of DONSON with colour coded domains (C) and 3D representation of these domains separation (B). (D) Mapping of the disease mutations described in (48) on human DONSON structure. Meier-Gorlin, Microcephalic Primordial Dwarfism MPD syndrome and Neu-Laxova syndrome mutations are mapped. The mutations marked in red do not have Xenopus homologous sequence. (E) DONSON mutant lacking unstructured N-terminus (DONSONΔN) or the flexible loop D3 from (B), (DONSONΔloop), was purified (Supplementary Figure 3C) and tested for rescue of DONSON-depleted egg extract in its ability to synthesise nascent DNA. (F) Indicated point mutants of DONSON (Xenopus DONSON with mutations homologous to patient derived human mutations) were purified (Supp Figure 3C) and tested as in (E).
	Supp Figure 1. DONSON interacts with terminated replisomes. (A) DNA replication reaction was established in Xenopus laevis egg extract supplemented with inactive mutant of p97 segregase and MLN4924 cullin E3 ligase inhibitor to block disassembly of replisomes in S-phase (as described in Sonneville et al 2017). Chromatin containing retained terminated replisomes was isolated, fragmented with benzonase and Mcm3 immunoprecipitaed. Proteins interacting with Mcm3 were analysed by mass spectrometry. Total spectral count and percentage coverage is presented for selected replisome components. (B) Polyclonal rabbit and shhep antibodies were raised against recombinant X.l.DONSON purified from bacteria. Protein band corresponding to DONSON within egg extract is ndicated. (C) Replicaton reaction was set up in egg extract supplemented with p97i NMS932 and chromatin isolated at indicated times. Chromatin samples were analysed by western blotting with indicated antibodies as in Figure 1. (D) As in (C) but the replication reaction was supplemented with cullin E3 ligase inhibitor MLN4924. (E) X.laevis 6HIS-DONSON expressed in bacteria and affinity purified.
	Supp Figure 2. (A) DNA replication was set up in egg extract either supplemented with p97i to accumulate post-termination replisome or with aohidicolin and caffeine to accumulate stalled and continously estabishing replisomes. Chromatin sample was isolated either in late (for p97 inhibitor, 90 min) or middle (for aphidicolin/caffeine, 60 min) S-phase, protein complexes released from chromatn by DNA digestion and non-specific control and DONSON(s) antibodies used for immunoprecipiatation. The fold enrichment of presented replication fators in DONSON IP over nonspecific conrol IP was coalculated and is preseneted. (B) TopBP1 was immunodepleted from egg extract. The efficiency of immunodepletion was analysed by western blotting against titration of original egg extract (top) and the ability of the immunodepleted extract to synthesise nascent DNA analysed by incorporation of α32P-dATP into synthesised DNA (bottom).
	Supp Figure 3. Conservation of DONSON structure (A) AlphaFold overlay of 3D structure of Xenopus DONSON (blue) and human DONSON (orange). Overlapping structure in green. (B) Comparison of XenopusDONSON (blue) and human DONSON (orange) primary sequences. Conserved sequence in green. (C) Purification of DONSON truncation and patient mutations indicted. (D) Titration of recombinant wt DONSON into DONSON-depleted egg extract. The % of control replication level of IgG-depleted egg extract is presented as mean of n=2 with SEM.

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