ImageVerifierCode 换一换
格式:PPT , 页数:101 ,大小:1.89MB ,
资源ID:373333      下载积分:2000 积分
快捷下载
登录下载
邮箱/手机:
温馨提示:
如需开发票,请勿充值!快捷下载时,用户名和密码都是您填写的邮箱或者手机号,方便查询和重复下载(系统自动生成)。
如填写123,账号就是123,密码也是123。
特别说明:
请自助下载,系统不会自动发送文件的哦; 如果您已付费,想二次下载,请登录后访问:我的下载记录
支付方式: 支付宝扫码支付 微信扫码支付   
注意:如需开发票,请勿充值!
验证码:   换一换

加入VIP,免费下载
 

温馨提示:由于个人手机设置不同,如果发现不能下载,请复制以下地址【http://www.mydoc123.com/d-373333.html】到电脑端继续下载(重复下载不扣费)。

已注册用户请登录:
账号:
密码:
验证码:   换一换
  忘记密码?
三方登录: 微信登录  

下载须知

1: 本站所有资源如无特殊说明,都需要本地电脑安装OFFICE2007和PDF阅读器。
2: 试题试卷类文档,如果标题没有明确说明有答案则都视为没有答案,请知晓。
3: 文件的所有权益归上传用户所有。
4. 未经权益所有人同意不得将文件中的内容挪作商业或盈利用途。
5. 本站仅提供交流平台,并不能对任何下载内容负责。
6. 下载文件中如有侵权或不适当内容,请与我们联系,我们立即纠正。
7. 本站不保证下载资源的准确性、安全性和完整性, 同时也不承担用户因使用这些下载资源对自己和他人造成任何形式的伤害或损失。

版权提示 | 免责声明

本文(The Problem of Detecting Differentially Expressed Genes.ppt)为本站会员(figureissue185)主动上传,麦多课文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知麦多课文库(发送邮件至master@mydoc123.com或直接QQ联系客服),我们立即给予删除!

The Problem of Detecting Differentially Expressed Genes.ppt

1、,The Problem of Detecting Differentially Expressed Genes,Class 1,Class 2,Fold Change is the Simplest MethodCalculate the log ratio between the two classes and consider all genes that differ by more than an arbitrary cutoff value to be differentially expressed. A two-fold difference is often chosen.F

2、old change is not a statistical test.,(1) For gene consider the null hypothesis of no association between its expression level and its class membership.,Test of a Single Hypothesis,(3) Perform a test (e.g Students t-test) for each gene.,(2) Decide on level of significance (commonly 5%).,(4) Obtain P

3、-value corresponding to that test statistic.,(5) Compare P-value with the significance level. Then either reject or retain the null hypothesis.,Two-Sample t-Statistic,Students t-statistic:,Two-Sample t-Statistic,Pooled form of the Students t-statistic, assumed common variance in the two classes:,Two

4、-Sample t-Statistic,Modified t-statistic of Tusher et al. (2001):,TRUE,PREDICTED,Types of Errors in Hypothesis Testing,Multiplicity Problem,Further: Genes are co-regulated, subsequently there is correlation between the test statistics.,When many hypotheses are tested, the probability of a false posi

5、tive increases sharply with the number of hypotheses.,Suppose we measure the expression of 10,000 genes in a microarray experiment.,If all 10,000 genes were not differentially expressed, then we would expect for:P= 0.05 for each test, 500 false positives.P= 0.05/10,000 for each test, .05 false posit

6、ives.,Example,Controlling the Error Rate,Methods for controlling false positives e.g. Bonferroni are too strict for microarray analyses Use the False Discovery Rate instead (FDR)(Benjamini and Hochberg 1995),Methods for dealing with the Multiplicity Problem,The Bonferroni Method controls the family

7、wise error rate (FWER) i.e. the probability that at least one false positive error will be made,The False Discovery Rate (FDR) emphasizes the proportion of false positives among the identified differentially expressed genes.,Too strict for gene expression data, tries to make it unlikely that even on

8、e false rejection of the null is made, may lead to missed findings,Good for gene expression data says something about the chosen genes,The FDR is essentially the expectation of the proportion of false positives among the identified differentially expressed genes.,False Discovery Rate Benjamini and H

9、ochberg (1995),Possible Outcomes for N Hypothesis Tests,where,Positive FDR,Lindsay, Kettenring, and Siegmund (2004).A Report on the Future of Statistics.Statist. Sci. 19.,Key papers on controlling the FDR,Genovese and Wasserman (2002) Storey (2002, 2003)Storey and Tibshirani (2003a, 2003b)Storey, Ta

10、ylor and Siegmund (2004)Black (2004)Cox and Wong (2004),Controlling FDR,Benjamini and Hochberg (1995),Benjamini-Hochberg (BH) Procedure,Controls the FDR at level a when the P-values following the null distribution are independent and uniformly distributed.,(1) Let be the observed P-values.,(2) Calcu

11、late .,(3) If exists then reject null hypotheses corresponding to. Otherwise, reject nothing.,Example: Bonferroni and BH Tests,Suppose that 10 independent hypothesis tests are carried out leading to the following ordered P-values:,0.00017 0.00448 0.00671 0.00907 0.01220 0.33626 0.39341 0.53882 0.581

12、25 0.98617,(a) With a = 0.05, the Bonferroni test rejects any hypothesis whose P-value is less than a / 10 = 0.005.,Thus only the first two hypotheses are rejected.,(b) For the BH test, we find the largest k such that P(k) ka / N.,Here k = 5, thus we reject the first five hypotheses.,q-VALUE,q-value

13、 of a gene j is expected proportion of false positives when calling that gene significant.P-value is the probability under the null hypothesis of obtaining a value of the test statistic as or more extreme than its observed value. The q-value for an observed test statistic can be viewed as the expect

14、ed proportion of false positives among all genes with their test statistics as or more extreme than the observed value.,LIST OF SIGNIFICANT GENES,Call all genes significant if pj 0.05 or Call all genes significant if qj 0.05 to produce a set of significant genes so that a proportion of them (0.05) i

15、s expected to be false (at least for a large no. of genes not necessarily independent),BRCA1 versus BRCA2-mutation positive tumours (Hedenfalk et al., 2001),BRCA1 (7) versus BRCA2-mutation (8) positive tumours, p=3226 genesP=.001 gave 51 genes differentially expressedP=0.0001 gave 9-11 genes,Using q

16、0.05, gives 160 genes are taken to be significant.It means that approx. 8 of these 160 genes are expected to be false positives.Also, it is estimated that 33% of the genes are differentially expressed.,Permutation Method,The null distribution has a resolution on the order of the number of permutatio

17、ns. If we perform B permutations, then the P-value will be estimated with a resolution of 1/B. If we assume that each gene has the same null distribution and combine the permutations, then the resolution will be 1/(NB) for the pooled null distribution.,Null Distribution of the Test Statistic,Using j

18、ust the B permutations of the class labels for the gene-specific statistic Wj , the P-value for Wj = wj is assessed as:,where w(b)0j is the null version of wj after the bth permutation of the class labels.,If we pool over all N genes, then:,Class 1 Class 2,Gene 1 A1(1) A2(1) A3(1) B4(1) B5(1) B6(1),

19、Gene 2 A1(2) A2(2) A3(2) B4(2) B5(2) B6(2),Suppose we have two classes of tissue samples, with three samples from each class. Consider the expressions of two genes, Gene 1 and Gene 2.,Null Distribution of the Test Statistic: Example,Class 1 Class 2,Gene 1 A1(1) A2(1) A3(1) B4(1) B5(1) B6(1),Gene 2 A

20、1(2) A2(2) A3(2) B4(2) B5(2) B6(2),Gene 1 A1(1) A2(1) A3(1) A4(1) A5(1) A6(1),To find the null distribution of the test statistic for Gene 1, we proceed under the assumption that there is no difference between the classes (for Gene 1) so that:,Perm. 1 A1(1) A2(1) A4(1) A3(1) A5(1) A6(1) . There are

21、10 distinct permutations.,And permute the class labels:,Ten Permutations of Gene 1,A1(1) A2(1) A3(1) A4(1) A5(1) A6(1)A1(1) A2(1) A4(1) A3(1) A5(1) A6(1)A1(1) A2(1) A5(1) A3(1) A4(1) A6(1)A1(1) A2(1) A6(1) A3(1) A4(1) A5(1)A1(1) A3(1) A4(1) A2(1) A5(1) A6(1)A1(1) A3(1) A5(1) A2(1) A4(1) A6(1)A1(1) A

22、3(1) A6(1) A2(1) A4(1) A5(1)A1(1) A4(1) A5(1) A2(1) A3(1) A6(1)A1(1) A4(1) A6(1) A2(1) A3(1) A5(1)A1(1) A5(1) A6(1) A2(1) A3(1) A4(1),As there are only 10 distinct permutations here, the null distribution based on these permutations is too granular. Hence consideration is given to permuting the labe

23、ls of each of the other genes and estimating the null distribution of a gene based on the pooled permutations so obtained. But there is a problem with this method in that the null values of the test statistic for each gene does not necessarily have the theoretical null distribution that we are tryin

24、g to estimate.,Suppose we were to use Gene 2 also to estimate the null distribution of Gene 1. Suppose that Gene 2 is differentially expressed, then the null values of the test statistic for Gene 2 will have a mixed distribution.,Class 1 Class 2,Gene 1 A1(1) A2(1) A3(1) B4(1) B5(1) B6(1),Gene 2 A1(2

25、) A2(2) A3(2) B4(2) B5(2) B6(2),Gene 2 A1(2) A2(2) A3(2) B4(2) B5(2) B6(2),Perm. 1 A1(2) A2(2) B4(2) A3(2) B5(2) B6(2).,Permute the class labels:,Example of a null case: with 7 N(0,1) points and 8 N(0,1) points; histogram of the pooled two-sample t-statistic under 1000 permutations of the class labe

26、ls with t13 density superimposed.,ty,Example of a null case: with 7 N(0,1) points and 8 N(10,9) points; histogram of the pooled two-sample t-statistic under 1000 permutations of the class labels with t13 density superimposed.,ty,The SAM Method,Use the permutation method to calculate the null distrib

27、ution of the modified t-statistic (Tusher et al., 2001).,The order statistics t(1), . , t(N) are plotted against their null expectations above. A good test in situations where there are more genes being over-expressed than under-expressed, or vice-versa.,TRUE,PREDICTED,FDR ,R,FNDR ,The FDR and other

28、 error rates,TRUE,PREDICTED,FDR ,R,FNR =,The FDR and other error rates,FDR = B / (B + D) = 475 / 875 = 54%,FNDR = C / (A + C) = 100 / 9125 = 1%,Toy Example with 10,000 Genes,Two-component mixture model,is the proportion of genes that are not,differentially expressed, and,Use of the P-Value as a Summ

29、ary Statistic (Allison et al., 2002),Instead of using the pooled form of the t-statistic, we can work with the value pj, which is the P-value associated with tj in the test of the null hypothesis of no difference in expression between the two classes.,The distribution of the P-value is modelled by t

30、he h-component mixture model,where a11 = a12 = 1.,Use of the P-Value as a Summary Statistic,Under the null hypothesis of no difference in expression for the jth gene, pj will have a uniform distribution on the unit interval; ie the b1,1 distribution.,The ba1,a2 density is given by,where,Efron B, Tib

31、shirani R, Storey JD, Tusher V (2001) Empirical Bayes analysis of a microarray experiment. JASA 96,1151-1160. Efron B (2004) Large-scale simultaenous hypothesis testing: the choice of a null hypothesis. JASA 99, 96-104. Efron B (2004) Selection and Estimation for Large-Scale Simultaneous Inference.

32、Efron B (2005) Local False Discovery Rates. Efron B (2006) Correlation and Large-Scale Simultaneous Significance Testing.,McLachlan GJ, Bean RW, Ben-Tovim Jones L, Zhu JX. Using mixture models to detect differentially expressed genes. Australian Journal of Experimental Agriculture 45, 859-866.McLach

33、lan GJ, Bean RW, Ben-Tovim Jones L. A simple implentation of a normal mixture approach to differential gene expression in multiclass microarrays. Bioinformatics 26. To appear.,Two component mixture model,Using Bayes Theorem, we calculate the posterior probability that gene j is not differentially ex

34、pressed:,0 is the proportion of genes that are not differentially expressed. The two-component mixture model is:,0(wj) c0,then this decision minimizes the (estimated) Bayes risk,If we conclude that gene j is differentially expressed if:,where,where e01 is the probability of a false positive and e10

35、is the probability of a false negative.,Estimated FDR,where,Similarly, the false positive rate is given by,and the false non-discovery rate and false negative rate by:,F0: N(0,1), 0=0.9 F1: N(1,1), 1=0.1Reject H0 if z20(2) = 0.99972 but FDR=0.17,F0: N(0,1), 0=0.6 F1: N(1,1), 1=0.4Reject H0 if z20(2)

36、 = 0.251 but FDR=0.177,Glonek and Solomon (2003),Gene Statistics: Two-Sample t-Statistic,Students t-statistic,Pooled form of the Students t-statistic, assumed common variance in the two classes,Modified t-statistic of Tusher et al. (2001),1. Obtain the z-score for each of the genes,The Procedure,2.

37、Rank the genes on the basis of the z-scores, starting with the largest ones (the same ordering as with the P-values, pj).,3. The posterior probability of non-differential expression of gene j, is given by 0(zj).,4. Conclude gene j to be differentially expressed if0(zj) c0,0(zj) c,If 0/1 9,then,e.g.

38、c = 0.2,Suppose,0/ 1 0.9,then,0(zj) c,0(zj) 0.2 if,Much stronger level of evidence against the null than in standard one-at-a-time testing.,e.g.,Zj N(,1),H0 : = 0 vs H1 : = 2.8,Rejecting H0 if |Zj| 1.96 yields a two-sided test of size 0.05 and power 0.80.f1(1.96)/f0(1.96) = 4.8.,Z-scores, null case,

39、Z-scores, +1,Z-scores, +2,Z-scores, +3,zj,j,Use of Wilson-Hilferty Transformation as in Broet et al. (2004),Plot of approximate z-scores obtained by Wilson-Hilferty transformation of simulated values of F-statistic with 1 and 8 degrees of freedom.,EMMIX-FDR,A program has been written in R which inte

40、rfaces with EMMIX to implement the algorithm described in McLachlan et al (2006).We fit a mixture of two normal componentsto test statistics calculated from the gene expression data.,When we equate the sample mean and variance of the mixture to their population counterparts, we obtain:,When we are w

41、orking with the theoretical null, we can easily estimate the mean and variance of the non-null component with the following formulae.,Following the approach of Storey and Tibshirani (2003) we can obtain an initial estimate for 0 as follows:,This estimate of 0 is used as input to EMMIX as part of the

42、 initial parameter estimates. Thus no random or k-means starts are required, as is usually the case.There are two different versions of EMMIX used, the standard version for the empirical null and a modified version for the theoretical null which fixes the mean and variance of the null component to b

43、e 0 and 1 respectively.,Theoretical and empirical nulls,Efron (2004) suggested the use of two kinds of null component: the theoretical and the empirical null. In the theoretical case the null component has mean 0 and variance 1 and the empirical null has unrestricted mean and variance.,Examples,We e

44、xamined the performance of EMMIX-FDR on three well-known data setsfrom the literature.Alon colon cancer data (1999) Hedenfalk breast cancer data (2001) vant Wout HIV data (2003),Hedenfalk Breast Cancer Data,Hedenfalk et al. (2001) used cDNA arrays to obtain gene expression profiles of tumours from c

45、arriers of either the BRCA1 or BRCA2 mutation (hereditary breast cancers), as well as sporadic breast cancer.We consider their data set of M = 15 patients, comprising two patient groups: BRCA1 (7) versus BRCA2 - mutation positive (8), with N = 3,226 genes.,The problem is to find genes which are diff

46、erentially expressed between the BRCA1 and BRCA2 patients.,Hedenfalk et al. (2001) NEJM, 344, 539-547,Fitto the N values of wj (based on pooled two-sample t-statistic),j th gene is taken to be differentially expressed if:,Two component model for the Breast Cancer Data,Fitting two component mixture m

47、odel to Hedenfalk data,Null,NonNull (DE genes),Estimates of 0 for Hedenfalk data,0.52 (Broet, 2004) 0.64 (Gottardo, 2006) 0.61 (Ploner et al, 2006) 0.47 (Storey, 2002) Using a theoretical null, we estimated 0 to be 0.65.,We used pj = 2 F13(-|wj|)Similar results where pj obtained by permutation metho

48、ds.,c0 = 0.1,Ranking and Selecting the Genes,FDR= Sum/R = 0.06,Proportion of False Negatives = 1 Sum1/ R1,Local FDR,Estimated FDR for various levels of c0,Estimated FDR and other error rates for various levels of threshold c0 applied to the posterior probability of nondifferential expression for the

49、 breast cancer data (Nr=number of selected genes),Storey and Tibshirani (2003) PNAS, 100, 9440-9445,Comparison of identified DE genes,Our method (143),Hedenfalk (175),Storey and Tibshirani (160),101,6,12,8,39,29,24,Uniquely Identified Genes: Differentially Expressed between BRCA1 and BRCA2,1. Obtain the z-score for each of the genes,

copyright@ 2008-2019 麦多课文库(www.mydoc123.com)网站版权所有
备案/许可证编号:苏ICP备17064731号-1