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J. M. Friedman, Ágnes Baross, Allen D

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1 Oligonucleotide Microarray Analysis of Genomic Imbalance in Children with Mental Retardation 
J.M. Friedman, Ágnes Baross, Allen D. Delaney, Adrian Ally, Laura Arbour, Jennifer Asano, Dione K. Bailey, Sarah Barber, Patricia Birch, Mabel Brown-John, Manqiu Cao, Susanna Chan, David L. Charest, Noushin Farnoud, Nicole Fernandes, Stephane Flibotte, Anne Go, William T. Gibson, Robert A. Holt, Steven J.M. Jones, Giulia C. Kennedy, Martin Krzywinski, Sylvie Langlois, Haiyan I. Li, Barbara C. McGillivray, Tarun Nayar, Trevor J. Pugh, Evica Rajcan-Separovic, Jacqueline E. Schein, Angelique Schnerch, Asim Siddiqui, Margot I. Van Allen, Gary Wilson, Siu-Li Yong, Farah Zahir, Patrice Eydoux, Marco A. Marra  The American Journal of Human Genetics  Volume 79, Issue 3, Pages (September 2006) DOI: /507471 Copyright © 2006 The American Society of Human Genetics Terms and Conditions

2 Figure 1 Flow diagram showing algorithm used for detection of CNVs by use of WGSA with Mapping 100K arrays. HMM = hidden Markov model. The American Journal of Human Genetics  , DOI: ( /507471) Copyright © 2006 The American Society of Human Genetics Terms and Conditions

3 Figure 2 A CNV on chromosome 2 in the affected child of family A, dChip-smoothed copy-number (CN) estimate with a window of 38 SNPs, showing a 1-copy deletion. B, Diagram showing t scores calculated for a sliding window of 38 SNPs that compare the copy number estimated by dChip for SNPs within the window with the copy number estimated for all other SNPs on the same chromosome. The high (negative) t scores associated with the deletion indicate that this deviation in copy number is unlikely to have occurred by chance. In both panels, the X-axis shows the nucleotide position in Mb. The American Journal of Human Genetics  , DOI: ( /507471) Copyright © 2006 The American Society of Human Genetics Terms and Conditions

4 Figure 3 Inherited CNV demonstrated by WGSA with Mapping 100K arrays. A, Plot of t scores for chromosome 2 in father, mother, and child in family 0674, by use of a 21-SNP window. The SNPs are ordered along the X-axis from pter to qter, with the location shown in Mb. The child with MR inherited the CNV (blue oval) from his unaffected father. B, FISH confirmation of the inherited CNV on 2q34. In the father and child, one chromosome 2 (white arrowheads) lacks a signal for probe RP11-93G7, whereas the signal is present on the other chromosome 2 (red arrowheads). In the mother, the signal for probe RP11-93G7 is seen on both chromosomes 2 (red arrowheads). The American Journal of Human Genetics  , DOI: ( /507471) Copyright © 2006 The American Society of Human Genetics Terms and Conditions

5 Figure 4 De novo submicroscopic genomic deletion, del(2)(p16.3p16.3), identified by WGSA with Mapping 100K arrays in family A, The t scores for the CNV in comparison with the rest of the chromosome, by use of a window size of 20 SNPs. The SNPs are ordered along the X-axis from pter to qter, with the location shown in Mb. B, FISH confirmation of the CNV in the affected child by use of probe RP G3. The white arrowhead indicates the deletion-containing chromosome 2 without the signal. The green arrowhead indicates the normal homologue, which shows the signal. The American Journal of Human Genetics  , DOI: ( /507471) Copyright © 2006 The American Society of Human Genetics Terms and Conditions

6 Figure 5 De novo submicroscopic genomic deletions identified by WGSA with Mapping 100K arrays in the affected child of families 1895, 3476, 4818, 5566, 6545, and Panels A, C, E, G, I, K, and M show the t scores for each CNV in comparison with the rest of the chromosome, by use of the window size given below. The SNPs are ordered along the X-axis from pter to qter, with the location shown in Mb. Panels B, D, F, H, J, L, and N show FISH confirmation of the CNV in the affected child, by use of the probe given below. The white arrowhead indicates the deleted chromosome without the signal. The red or green arrowhead indicates the normal homologue, which shows the signal. A, Family 1895, chromosome 13, window of 20 SNPs. B, Family 1895, probe RP11-26D3, del(13)(q12.11q12.13). C, Family 3476, chromosome 4, window of 30 SNPs. D, Family 3476, probe RP11-7G22, del(4)(q21.21q22.1). E, Family 4818, chromosome 12, window of 20 SNPs. F, Family 4818, probe RP11-91K23, del(12)(q14.2q15). G, Family 5566, chromosome 14, window of 5 SNPs. The de novo CNV is shown inside the blue oval. H, Family 5566, probe CTD-2136K6, del(14)(q11.2q11.2). I, Family 6545, chromosome 7, window of 20 SNPs. J, Family 6545, probe RP11-802L1, del(7)(p22.2p22.1). K, Family 7807, chromosome 22, window of 20 SNPs. L, Family 7807, probe RP11-79G21, del(22)(q12.1q12.1). M, Family 8326, chromosome 14, window of 20 SNPs. N, Family 8326, probe RP11-340M24, del(14)(q11.2q11.2). The American Journal of Human Genetics  , DOI: ( /507471) Copyright © 2006 The American Society of Human Genetics Terms and Conditions

7 Figure 6 De novo submicroscopic genomic duplication, dup(16)(p13.3p13.3), identified by WGSA with Mapping 100K arrays in family A, The t scores for the CNV in comparison with the rest of the chromosome, by use of a window size of 20 SNPs. The SNPs are ordered along the X-axis from pter to qter, with the location shown in Mb. The de novo CNV is shown inside the blue oval. B, FISH confirmation of the CNV in the affected child, by use of probe G248P82513E10 in metaphase cells (left) and probe RP11-397B22 in interphase cells (right). In the metaphase spread, the duplication is indicated by the red arrowhead, and the normal chromosome is indicated by the blue arrowhead. The signal is duplicated on one chromosome 16. The American Journal of Human Genetics  , DOI: ( /507471) Copyright © 2006 The American Society of Human Genetics Terms and Conditions

8 Figure 7 De novo submicroscopic genomic duplication, dup(17)(q21.33q21.33), identified by WGSA with Mapping 100K arrays in family A, The t scores for each CNV in comparison with the rest of the chromosome, by use of a window size of 8 SNPs. The SNPs are ordered along the X-axis from pter to qter, with the location shown in Mb. The de novo CNV is shown inside the blue oval. B, FISH confirmation of the CNV in the affected child, by use of probes RP11-962N5 (green) and RP11-121F10 (red) in metaphase (left) and interphase (right) cells. In the metaphase spread, the duplication is shown at the red arrowhead, and the normal chromosome is shown at the blue arrowhead. The red signal is duplicated on one chromosome 17; the green signal does not appear duplicated but cross-hybrizes to chromosome 6qter. The American Journal of Human Genetics  , DOI: ( /507471) Copyright © 2006 The American Society of Human Genetics Terms and Conditions

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