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I wish to calculate the correlation matrix in R for the probesets and the different organs.

I did it in the following way:

The initial matrix (of probesets which are differentially expressed with corresponding signal intensity values) is

                         [,1]      [,2]      [,3]      [,4]      [,5]
  AFFX-r2-P1-cre-5_at  12.282799 12.350387 12.383974 12.363040 12.162706  
  AFFX-r2-P1-cre-3_at  12.522336 12.352319 12.435931 12.500593 12.061709  
  AFFX-r2-Ec-bioD-5_at  9.695228  9.632995  9.677720  9.715962  9.432542  
  267584_at             5.044394  4.700440  2.000000  2.584963  2.584963  
  267562_at             8.149747  7.936638  9.426265  9.455327  6.475733  
  267511_at             8.550747  8.285402  7.285402  7.607330  8.511753  

                         [,6]      [,7]      [,8]     [,9]     [,10]     [,11]
   AFFX-r2-P1-cre-5_at  12.703038 13.003694 13.109667 0.000000 13.116019 13.127027
   AFFX-r2-P1-cre-3_at  12.926667 13.187816 13.160974 7.721099 13.319108 13.338179
   AFFX-r2-Ec-bioD-5_at 10.233620 10.636625 11.235416 0.000000 11.061371 11.276124
   267584_at             4.523562  3.169925  2.000000 0.000000  3.906891  4.087463
   267562_at             7.383704  8.066089  5.392317 0.000000  4.807355  6.321928
   267511_at             8.550747  6.266787  4.523562 1.000000  6.475733  6.741467
                         [,12]     [,13]     [,14]     [,15]     [,16]
   AFFX-r2-P1-cre-5_at  13.346237 12.450180 13.071295 12.100991 12.530650
   AFFX-r2-P1-cre-3_at  13.627876 12.566054 13.415214 12.266201 12.658658
   AFFX-r2-Ec-bioD-5_at 11.336507 10.166163 11.061371  9.259743  9.896332
   267584_at             4.584963  4.247928  4.523562  4.459432  4.523562
   267562_at             5.169925  4.169925  5.807355  9.353147  8.011227
   267511_at             6.820179  6.169925  6.375039  7.754888  8.430453
                            [,17]     [,18]     [,19]     [,20]     [,21]
 AFFX-r2-P1-cre-5_at  12.242876 12.266787 11.953469 12.125736 11.880731
 AFFX-r2-P1-cre-3_at  12.505315 12.677499 12.203042 12.332037 12.149747
 AFFX-r2-Ec-bioD-5_at  9.929258  9.923327  9.442943  9.569856  9.144658
 267584_at             3.700440  1.584963  3.807355  1.584963  2.000000
 267562_at             7.409391  7.761551  7.679480  7.475733  7.199672
 267511_at             7.554589  7.483816  7.734710  7.409391  6.820179
                        [,22]     [,23]     [,24]     [,25]     [,26]
AFFX-r2-P1-cre-5_at  12.576012 12.159241 12.193833 12.157031 13.043369
AFFX-r2-P1-cre-3_at  12.672867 12.353147 12.501837 12.408064 13.135228
AFFX-r2-Ec-bioD-5_at  9.932215  9.455327  9.923327  9.344296 10.373953
267584_at             2.584963  4.087463  1.584963  3.459432  2.321928
267562_at             7.651052  7.108524  7.774787  8.891784  8.005625
267511_at             8.596190  7.894818  7.276124  9.269127  9.144658
                         [,27]     [,28]     [,29]     [,30]     [,31]
AFFX-r2-P1-cre-5_at  12.106563 13.031184 12.797459 12.883598 12.348175
AFFX-r2-P1-cre-3_at  12.313450 13.037547 12.930737 13.025832 12.509528
AFFX-r2-Ec-bioD-5_at  9.505812 10.286558 10.145932 10.143383  9.705632
267584_at             4.000000  4.169925  3.321928  3.807355  2.321928
267562_at             6.209453  8.980140  8.599913  8.543032  8.321928
267511_at             8.044394  7.515700  7.569856  7.491853  7.754888
                       [,32]     [,33]     [,34]     [,35]     [,36]
 AFFX-r2-P1-cre-5_at  12.069450 12.439831 12.162706 12.049168 12.251482
 AFFX-r2-P1-cre-3_at  12.426789 12.641600 12.048487 12.269127 12.519145
 AFFX-r2-Ec-bioD-5_at  9.525521  9.781360  9.505812  9.366322  9.364135
267584_at             2.321928  4.087463  4.000000  4.459432  2.807355
267562_at             7.562242  7.948367  5.357552  8.266787  8.103288
267511_at             7.727920  7.845490  7.044394  7.727920  7.800900
                        [,37]     [,38]     [,39]     [,40]     [,41]
   AFFX-r2-P1-cre-5_at  11.986553 12.039947 12.272630 12.011926 11.953833
   AFFX-r2-P1-cre-3_at  12.250891 12.405141 12.523072 12.170238 12.194141
   AFFX-r2-Ec-bioD-5_at  9.339850  9.620220  9.330917  8.912889 10.107217
   267584_at             2.807355  4.087463  1.584963  5.247928  3.169925
   267562_at             8.483816  6.357552  6.686501  5.392317  7.672425
   267511_at             8.129283  7.434628  8.016808  7.228819  7.607330
                            [,42]     [,43]     [,44]     [,45]     [,46]
   AFFX-r2-P1-cre-5_at  12.428360 12.240195 12.645884 12.788718 12.357277
   AFFX-r2-P1-cre-3_at  12.510270 12.465821 12.720244 12.904635 12.600378
   AFFX-r2-Ec-bioD-5_at  9.712527  9.988685 10.483816  9.682995 10.398744
   267584_at             3.321928  2.321928  2.584963  2.321928  2.000000
   267562_at             6.426265  7.971544  7.768184  7.033423  6.965784
   267511_at             5.930737  7.139551  7.055282  6.491853  6.794416
                           [,47]     [,48]     [,49]     [,50]     [,51]
     AFFX-r2-P1-cre-5_at  12.525031 13.094573 12.258860 12.294334 12.213712
     AFFX-r2-P1-cre-3_at  12.613559 12.981032 12.313450 12.353698 12.316564
     AFFX-r2-Ec-bioD-5_at 10.476746  9.885696  9.853310 10.067434 10.019591
     267584_at             2.000000  3.321928  5.977280  5.087463  4.321928
     267562_at             4.954196  1.000000  6.149747  6.303781  2.321928
     267511_at             4.523562  8.339850  3.000000  4.807355  6.523562
                         [,52]
      AFFX-r2-P1-cre-5_at  12.864573
      AFFX-r2-P1-cre-3_at  12.579552
      AFFX-r2-Ec-bioD-5_at        NA
      267584_at             2.321928
      267562_at             2.584963
      267511_at             8.118941

and I calculated the correlation matrix as follows:

matrix=cor(df,use="everything",method="spearman")
head(matrix)
       [,1]      [,2]      [,3]      [,4]      [,5]          [,6]      [,7]
   [1,] 1.0000000 0.8706335 0.9415289 0.8882720 0.7496661 0.7677754 0.7101537  
   [2,] 0.8706335 1.0000000 0.8753038 0.9139146 0.8657389 0.8728145 0.7866262  
   [3,] 0.9415289 0.8753038 1.0000000 0.9365893 0.7352165 0.7361438 0.7512819  
   [4,] 0.8882720 0.9139146 0.9365893 1.0000000 0.7786139 0.7541371 0.7989378  
   [5,] 0.7496661 0.8657389 0.7352165 0.7786139 1.0000000 0.9237363 0.8158172  

        [,8]      [,9]     [,10]     [,11]     [,12]     [,13]     [,14]
   [1,] 0.6850204 0.1076376 0.7115003 0.7188850 0.6858355 0.6866870 0.7074814
    [2,] 0.7700608 0.1340716 0.7803210 0.7941828 0.7233849 0.7487338 0.8038314
   [3,] 0.7194477 0.1147884 0.7036833 0.7321756 0.6785246 0.6848235 0.7173518
   [4,] 0.7598686 0.1179027 0.7391587 0.7867352 0.7049975 0.7012802 0.7621407
   [5,] 0.8215223 0.1522002 0.8797406 0.8454215 0.7879358 0.8401237 0.8827259
   [6,] 0.7861685 0.1427164 0.8323513 0.7838602 0.7514068 0.8025285 0.8325823
           [,15]     [,16]     [,17]     [,18]     [,19]     [,20]     [,21]
   [1,] 0.9150581 0.9519624 0.9604626 0.9578311 0.9564827 0.9288393 0.9414993
   [2,] 0.8730051 0.8700863 0.8684122 0.8796466 0.9010115 0.8988891 0.8943165
   [3,] 0.9625398 0.9014312 0.9426812 0.9492347 0.9458953 0.9378602 0.9360394
   [4,] 0.9460806 0.8608069 0.8935226 0.9049138 0.9305753 0.9381641 0.9246137
   [5,] 0.7301978 0.7636059 0.7570429 0.7662669 0.7772868 0.7646628 0.7597487
   [6,] 0.7351482 0.8017182 0.7739689 0.7820210 0.7821361 0.7809003 0.7849781
           [,22]     [,23]     [,24]     [,25]     [,26]     [,27]     [,28]
   [1,] 0.8616353 0.9346945 0.9351661 0.9441598 0.8642953 0.8569422 0.7741355
   [2,] 0.8015023 0.8476367 0.9212922 0.8845663 0.9054520 0.8752423 0.8424130
   [3,] 0.8008076 0.8955289 0.9435462 0.9176882 0.8694535 0.8491021 0.8330767
   [4,] 0.7657146 0.8529175 0.9360617 0.8887811 0.8838811 0.8441554 0.9181425
   [5,] 0.7330904 0.7373031 0.7917172 0.7782860 0.8070257 0.7905109 0.7484566
   [6,] 0.8074441 0.7825895 0.7961903 0.8025123 0.8179181 0.8226224 0.7240530
           [,29]     [,30]     [,31]     [,32]     [,33]     [,34]     [,35]
  [1,]   0.7948048 0.8047385 0.8212897 0.8174624 0.9038094 0.7047574 0.8256138
  [2,] 0.8273273 0.8300392 0.8621190 0.8234582 0.8328302 0.7211293 0.8337005
  [3,] 0.8509661 0.8581010 0.8597556 0.8498601 0.8958353 0.7229861 0.8603199
  [4,] 0.9067611 0.8972589 0.9200848 0.8681479 0.8605159 0.7175663 0.8898564
  [5,] 0.7189853 0.7026407 0.7796182 0.7473894 0.7217395 0.6865784 0.7273942
  [6,] 0.7065363 0.7056330 0.7505533 0.7420262 0.7504381 0.7060788 0.7341452
         [,36]     [,37]     [,38]     [,39]     [,40]     [,41]     [,42]
 [1,] 0.8208191 0.8955079 0.8391931 0.8636463 0.7700305 0.8588717 0.7033789
 [2,] 0.8474392 0.8771487 0.7949403 0.7985588 0.7532367 0.8463211 0.7310256
 [3,] 0.8568450 0.9197582 0.8080794 0.8055523 0.7476391 0.8474330 0.7297926
 [4,] 0.9002964 0.9244805 0.7803719 0.7674940 0.7158851 0.8538328 0.7649674
 [5,] 0.7422201 0.7443078 0.7338899 0.7273828 0.6930108 0.7512893 0.6769127
 [6,] 0.7399594 0.7557872 0.7809691 0.7923851 0.7533288 0.7888349 0.7020894
         [,43]     [,44]     [,45]     [,46]     [,47]     [,48]     [,49]
 [1,] 0.8334948 0.8014518 0.7095645 0.7863467 0.6563865 0.4515126 0.5831991
 [2,] 0.8344253 0.8222209 0.7483889 0.8137218 0.6377846 0.4279956 0.5963245
 [3,] 0.8578271 0.8221961 0.7482551 0.8131245 0.6445430 0.4574007 0.6332150
 [4,] 0.8744031 0.8536781 0.7936019 0.8466116 0.6461558 0.4495002 0.6582728
 [5,] 0.7089746 0.7086639 0.6789083 0.7128545 0.6399272 0.4556581 0.5771899
 [6,] 0.7281142 0.7322898 0.6878004 0.7304317 0.6854687 0.4431268 0.5498575
         [,50]     [,51] [,52]
 [1,] 0.5966548 0.5161562    NA
 [2,] 0.6089229 0.4892975    NA
 [3,] 0.6454899 0.5276595    NA
 [4,] 0.6649009 0.5155207    NA
 [5,] 0.5930356 0.5052900    NA
 [6,] 0.5684693 0.5028788    NA

I feel that the correlation is quite high and maybe I commited a mistake somewhere. Is there any significant explanation for the same?

share|improve this question
    
The code looks ok to me. Have you looked at your data to see if it appears to be correlated? You can do it with image(as.matrix(df)). Also, you might want to set use="pairwise" to no let your single missing value ruin that whole sample. –  Backlin Aug 22 '12 at 15:08
    
The correlation is likely driven by variability between probes (rows), which is large compared to variability within probes (columns). Compare with cor(t(apply(df, 1, scale))). –  Martin Morgan Aug 22 '12 at 16:14
    
Would it be possible to cluster the correlation matrix and infer?? –  Stacey John Aug 23 '12 at 7:49
    
> hclust(matrix,method="complete",members=NULL) Error in if (n < 2) stop("must have n >= 2 objects to cluster") : argument is of length zero. I get the above error when I try to do a clustering with the correlation matrix. –  Stacey John Aug 23 '12 at 8:40
    
I tried transforming the correlation matrix into a dissimilarity matrix by using the command Dx <- as.dist(1 - matrix).Then I tried to cluster but am still not sure if am right in interpreting the cluster. –  Stacey John Aug 23 '12 at 9:21
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