Accessing data from Google Docs

The goal of this exercise is to make you familiar with how to download data from Google Sheets and to briefly review some key concepts R functions and coding concepts.

We’ll do the following things

(TODO: MAKE YOUR OWN OUTLINE)

Packages

## Google sheets download package
# comment this out when you are done
# install.packages("googlesheets4")
library(googlesheets4)

# comp bio packages
library(seqinr)
library(rentrez)
library(compbio4all)
library(Biostrings)

## Loading required package: BiocGenerics

## Loading required package: parallel

## 
## Attaching package: 'BiocGenerics'

## The following objects are masked from 'package:parallel':
## 
##     clusterApply, clusterApplyLB, clusterCall, clusterEvalQ,
##     clusterExport, clusterMap, parApply, parCapply, parLapply,
##     parLapplyLB, parRapply, parSapply, parSapplyLB

## The following objects are masked from 'package:stats':
## 
##     IQR, mad, sd, var, xtabs

## The following objects are masked from 'package:base':
## 
##     anyDuplicated, append, as.data.frame, basename, cbind, colnames,
##     dirname, do.call, duplicated, eval, evalq, Filter, Find, get, grep,
##     grepl, intersect, is.unsorted, lapply, Map, mapply, match, mget,
##     order, paste, pmax, pmax.int, pmin, pmin.int, Position, rank,
##     rbind, Reduce, rownames, sapply, setdiff, sort, table, tapply,
##     union, unique, unsplit, which.max, which.min

## Loading required package: S4Vectors

## Loading required package: stats4

## 
## Attaching package: 'S4Vectors'

## The following objects are masked from 'package:base':
## 
##     expand.grid, I, unname

## Loading required package: IRanges

## 
## Attaching package: 'IRanges'

## The following object is masked from 'package:grDevices':
## 
##     windows

## Loading required package: XVector

## Loading required package: GenomeInfoDb

## 
## Attaching package: 'Biostrings'

## The following object is masked from 'package:seqinr':
## 
##     translate

## The following object is masked from 'package:base':
## 
##     strsplit

Download data

ASSIGNING THE URL OF THE GOOGLE SHEET WITH ALL THE PROTEIN, GENES, MRNA, PID, ETC. ACCESSION NUMBERS AND DATA.

spreadsheet_sp <- "https://docs.google.com/spreadsheets/d/1spC_ZA3_cVuvU3e_Jfcj2nEIfzp-vaP7SA5f-qwQ1pg/edit?usp=sharing" 

THIS GETTING A FUNCTION FROM THE GOOGELSHEETS4 PACKAGE THAT WAS DOWNLOADED; MAKING SURE THE PACKAGE ISN’T CHEACKING THE USER ACCESS AUTHORIZATION.

# be sure to run this!
googlesheets4::gs4_deauth()   # <====== MUST RUN THIS

Third, we download our data.

NOTE!: sometimes Google Sheets or the function gets cranky and throws this error:

“Error in curl::curl_fetch_memory(url, handle = handle) : Error in the HTTP2 framing layer”

If that happens, just re-run the code.

# I include this again in case you missed is the first time : )
googlesheets4::gs4_deauth()  

# download
## NOTE: if you get an error, just run the code again
refseq_column <- read_sheet(ss = spreadsheet_sp, # the url
           sheet = "RefSeq_prot",                # the name of the worksheet
           range = "selenoprot!H1:H364",
           col_names = TRUE,
           na = "",                              # fill in empty spaces "" w/NA
           trim_ws = TRUE)

## v Reading from "human_gene_table".

## v Range ''selenoprot'!H1:H364'.

## NOTE: if you get an error, just run the code again

# for reasons we won't get into I'm going to do this
protein_refseq <- refseq_column$RefSeq_prot

THE FIRST 10 ACCESSION NUMBERS OF THE PROTEINS IN THE SPREADSHEET. THE RESULTS FROM ABOVE.

protein_refseq[1:10]

##  [1] "NP_000783.2"    "NP_998758.1"    "NP_001034804.1" "NP_001034805.1"
##  [5] "NP_001311245.1" NA               NA               "NP_054644.1"   
##  [9] "NP_001353425.1" "NP_000784.3"

GETTING THE GEN NAMES FROM THE NAME OF THE WORKSHEET WHICH WAS THE GOOGLE SPREADSHEET. OF THERE IS A SPACE(" ") IN THE RANGE WHERE R IS LOOKING, THEN INPUT NA INSTEAD. LASTLY, ASSIGNED THE GENE NAMES WITH THAT WAS IN THE GENE COLUMN TO A SINGLE VARIABLE.

# download
## NOTE: if you get an error, just run the code again
gene_name_column <- read_sheet(ss = spreadsheet_sp, # the url
           sheet = "gene",                # the name of the worksheet
           range = "selenoprot!A1:A364",
           col_names = TRUE,
           na = "",                              # fill in empty spaces "" w/NA
           trim_ws = TRUE)

## v Reading from "human_gene_table".

## v Range ''selenoprot'!A1:A364'.

## NOTE: if you get an error, just run the code again

# for reasons we won't get into I'm going to do this
gene <- gene_name_column$gene

Checking the data

GETTING THE WHAT, CLASSIFICATION, LENGTH, AND THE FIRST 10 PEROTEIN REFSEQ TRANSCRIPTS IN THE GOOGLE SPREADSHEET.

is(protein_refseq)

##  [1] "character"               "vector"                 
##  [3] "data.frameRowLabels"     "SuperClassMethod"       
##  [5] "character_OR_connection" "character_OR_NULL"      
##  [7] "atomic"                  "EnumerationValue"       
##  [9] "vector_OR_Vector"        "vector_OR_factor"

class(protein_refseq)

## [1] "character"

length(protein_refseq)

## [1] 363

protein_refseq[1:10]

##  [1] "NP_000783.2"    "NP_998758.1"    "NP_001034804.1" "NP_001034805.1"
##  [5] "NP_001311245.1" NA               NA               "NP_054644.1"   
##  [9] "NP_001353425.1" "NP_000784.3"

DETERMING THE INDEXES OF THE NA’S.

is.na(protein_refseq)

##   [1] FALSE FALSE FALSE FALSE FALSE  TRUE  TRUE FALSE FALSE FALSE FALSE  TRUE
##  [13]  TRUE FALSE FALSE FALSE FALSE FALSE FALSE FALSE  TRUE  TRUE  TRUE FALSE
##  [25] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE  TRUE  TRUE FALSE FALSE
##  [37] FALSE  TRUE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
##  [49] FALSE FALSE FALSE  TRUE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
##  [61] FALSE FALSE FALSE FALSE FALSE FALSE FALSE  TRUE FALSE FALSE FALSE FALSE
##  [73]  TRUE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE  TRUE
##  [85] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
##  [97] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [109] FALSE  TRUE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [121]  TRUE FALSE  TRUE FALSE FALSE FALSE FALSE FALSE FALSE FALSE  TRUE FALSE
## [133] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [145] FALSE FALSE FALSE FALSE  TRUE FALSE FALSE FALSE FALSE FALSE FALSE  TRUE
## [157] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [169] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [181] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [193] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE  TRUE  TRUE FALSE
## [205] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [217] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [229] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [241] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE  TRUE  TRUE
## [253] FALSE FALSE FALSE  TRUE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [265] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [277] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE  TRUE FALSE
## [289]  TRUE  TRUE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [301] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [313] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [325] FALSE FALSE FALSE FALSE FALSE FALSE  TRUE FALSE FALSE FALSE FALSE FALSE
## [337] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [349] FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE FALSE
## [361] FALSE FALSE FALSE

TABLING THE INDEXES OF THE NA’S, HWERE FALSE MEANS THAT THERE IS NO NA.

table(is.na(protein_refseq))

## 
## FALSE  TRUE 
##   334    29

PUTTING THE INDEXES OF THE NA’S INTO A TEMPORARY VARIABLE AND THEN GETTING ITS LENGTH.

# ...
temp <- is.na(protein_refseq)

# ....
protein_refseq[temp]

##  [1] NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA
## [26] NA NA NA NA

temp2 <- protein_refseq[temp]

# ...
length(temp2)

## [1] 29

MAKING A DATAFRAME

This is making a data frame to make it so that all the transcripts are all length lengths.

seleno_df <- data.frame(gene = gene,
                        protein_refseq = protein_refseq)

Giving the summary and top of the data frame matrix.

summary(seleno_df)

##      gene           protein_refseq    
##  Length:363         Length:363        
##  Class :character   Class :character  
##  Mode  :character   Mode  :character

head(seleno_df)

##   gene protein_refseq
## 1 DIO1    NP_000783.2
## 2 DIO1    NP_998758.1
## 3 DIO1 NP_001034804.1
## 4 DIO1 NP_001034805.1
## 5 DIO1 NP_001311245.1
## 6 DIO1           <NA>

REMOVING ALL THE NA’S

Getting rid of all the NA’s that are either not entered yet or the wrong accession number type. na.omit() get rid of EVERY row-the ENTIRE row- if there is even one NA, making the dimensions of matrix smaller in size.

# omit NAs
seleno_df_noNA <- na.omit(seleno_df)

# check length- should be shorter
dim(seleno_df)

## [1] 363   2

dim(seleno_df_noNA)

## [1] 334   2

SELECTION OF 1 ISOFORM

The same gene can appear multiple times because multiple isoforms are listed.

head(seleno_df_noNA)

##   gene protein_refseq
## 1 DIO1    NP_000783.2
## 2 DIO1    NP_998758.1
## 3 DIO1 NP_001034804.1
## 4 DIO1 NP_001034805.1
## 5 DIO1 NP_001311245.1
## 8 DIO2    NP_054644.1

GETTING THE UNIQUE NAME ENTRIES FROM THE DATA FRAME, GETTING THE LENGTH OF THE NUMBER OF UNIQUE ENTRIES AND THEN PRINT IT OUT. SLECTING JUST ONE ROW OF EACH ROW.

genes_unique <- unique(seleno_df_noNA$gene)
length(genes_unique)

## [1] 37

genes_unique

##  [1] "DIO1"     "DIO2"     "DIO3"     "GPX1"     "GPX2"     "GPX3"    
##  [7] "GPX4"     "GPX6"     "MSRB1"    "SELENOF"  "SELENOH"  "SELENOI" 
## [13] "SELENOK"  "SELENOM"  "SELENON"  "SELENOO"  "SELENOP"  "SELENOS" 
## [19] "SELENOT"  "SELENOV"  "SELENOW"  "SEPHS2"   "TXNRD1"   "TXNRD2"  
## [25] "TXNRD3"   "SELENOP1" "SELENOP2" "SELENOU"  "SELENOW1" "SELENOW2"
## [31] "SELENOE"  "SELENOJ"  "SELENOL"  "SELENOO1" "SELENOO2" "SELENOT1"
## [37] "SELENOT2"

unique() just gives us the unique elements. A related function, duplicated(), gives us the location of duplicated elements in the vector. FALSE means “not duplicated yet” or “first instance so far”.

i.dups <- duplicated(seleno_df_noNA$gene)

We can remove the duplicates using a form of reverse indexing where the “!” means “not”. (You don’t need to know this for the exam)

seleno_df_noNA[!i.dups, ]

##         gene protein_refseq
## 1       DIO1    NP_000783.2
## 8       DIO2    NP_054644.1
## 14      DIO3    NP_001353.4
## 15      GPX1    NP_000572.2
## 20      GPX2    NP_002074.2
## 24      GPX3    NP_002075.2
## 26      GPX4    NP_002076.2
## 29      GPX6    NP_874360.1
## 30     MSRB1    NP_057416.1
## 31   SELENOF    NP_004252.2
## 35   SELENOH    NP_734467.1
## 37   SELENOI    NP_277040.1
## 39   SELENOK    NP_067060.2
## 40   SELENOM    NP_536355.1
## 41   SELENON    NP_996809.1
## 43   SELENOO    NP_113642.1
## 44   SELENOP    NP_005401.3
## 47   SELENOS    NP_060915.2
## 49   SELENOT    NP_057359.2
## 50   SELENOV    NP_874363.1
## 53   SELENOW    NP_003000.1
## 54    SEPHS2    NP_036380.2
## 55    TXNRD1    NP_877393.1
## 62    TXNRD2    NP_006431.2
## 69    TXNRD3    NP_443115.1
## 232 SELENOP1 NP_001026780.2
## 233 SELENOP2 NP_001335698.1
## 236  SELENOU NP_001180447.1
## 268 SELENOW1 NP_001291715.2
## 269 SELENOW2 NP_001341647.1
## 334  SELENOE NP_001182713.2
## 338  SELENOJ NP_001180398.1
## 340  SELENOL NP_001177311.1
## 343 SELENOO1 NP_001038336.2
## 344 SELENOO2 NP_001335014.1
## 348 SELENOT1    NP_840075.2
## 350 SELENOT2 NP_001091957.2

Make a dataframe of non-duplicated genes

seleno_df_noDups <- seleno_df_noNA[!i.dups, ]
dim(seleno_df_noDups)

## [1] 37  2

USING RANDOM SEQUENCES

Let’s select 2 random sequences to work with. We’ll use SAMPLE() to select a random index number to get

First, lets make a vector that contains a unique number for each row of data

indices <- 1:nrow(seleno_df_noDups)

This would do the same thing

# with dim
indices <- 1:dim(seleno_df_noDups)[1]

# with length
indices <- 1:length(seleno_df_noDups$gene)

or hard-coded

indices <- 1:37

We can then use SAMPLE() to select 2 random numbers from this vector.

For x = we’ll use our vector of indices (1 to 37). For size we’ll use 2, since we want to pull out just 2 numbers. For replace we’ll use FALSE since we don’t want to be able to select the same number twice.

i.random.genes <- sample(x = indices,
                         size = 2,
                         replace = FALSE)

Hard coded this would be

i.random.genes <- sample(x = c(1:37),
                         size = 2,
                         replace = FALSE)

This gives me TWO indices values.

i.random.genes

## [1]  6 17

I can now use these index values to pull out TWO rows of data

seleno_df_noNA[i.random.genes, ]

##    gene protein_refseq
## 8  DIO2    NP_054644.1
## 24 GPX3    NP_002075.2

Hard coded, this would be something like this for whichever genes happen to have been selected

seleno_df_noNA[c(37,15), ]

##       gene protein_refseq
## 47 SELENOS    NP_060915.2
## 19    GPX1 NP_001316384.1

Downloading genes

I will now get TWO PROTEIN ACCESSION NUMBER FROM DATABASE.

rentrez::entrez_fetch(id = "NP_060915.2",
                      db = "protein",
                      rettype = "fasta")

## [1] ">NP_060915.2 selenoprotein S isoform 1 [Homo sapiens]\nMERQEESLSARPALETEGLRFLHTTVGSLLATYGWYIVFSCILLYVVFQKLSARLRALRQRQLDRAAAAV\nEPDVVVKRQEALAAARLKMQEELNAQVEKHKEKLKQLEEEKRRQKIEMWDSMQEGKSYKGNAKKPQEEDS\nPGPSTSSVLKRKSDRKPLRGGGYNPLSGEGGGACSWRPGRRGPSSGGUG\n\n"

rentrez::entrez_fetch(id = "NP_001316384.1",
                      db = "protein",
                      rettype = "fasta")

## [1] ">NP_001316384.1 glutathione peroxidase 1 isoform 5 [Homo sapiens]\nMCAARLAAAAAAAQSVYAFSARPLAGGEPVSLGSLRGKENAKNEEILNSLKYVRPGGGFEPNFMLFEKCE\nVNGAGAHPLFAFLREALPAPSDDATALMTDPKLITWSPVCRNDVAWNFEKFLVGPDGVPLRRYSRRFQTI\nDIEPDIEALLSQGPSCA\n\n"

ASSIGNING PROTEIN ACCESSION NUMBERS TO A VARIABLE.

prot1 <- rentrez::entrez_fetch(id = "NP_060915.2",
                      db = "protein",
                      rettype = "fasta")

prot2 <- rentrez::entrez_fetch(id = "NP_001316384.1",
                      db = "protein",
                      rettype = "fasta")

I can put them into a list like this

# make the vector
seleno_thingy <- vector("list", 1)


# add the first fasta
seleno_thingy[[1]] <- prot1

# See the result
seleno_thingy

## [[1]]
## [1] ">NP_060915.2 selenoprotein S isoform 1 [Homo sapiens]\nMERQEESLSARPALETEGLRFLHTTVGSLLATYGWYIVFSCILLYVVFQKLSARLRALRQRQLDRAAAAV\nEPDVVVKRQEALAAARLKMQEELNAQVEKHKEKLKQLEEEKRRQKIEMWDSMQEGKSYKGNAKKPQEEDS\nPGPSTSSVLKRKSDRKPLRGGGYNPLSGEGGGACSWRPGRRGPSSGGUG\n\n"

# add the first fasta
seleno_thingy[[2]] <- prot2

# see the result
seleno_thingy

## [[1]]
## [1] ">NP_060915.2 selenoprotein S isoform 1 [Homo sapiens]\nMERQEESLSARPALETEGLRFLHTTVGSLLATYGWYIVFSCILLYVVFQKLSARLRALRQRQLDRAAAAV\nEPDVVVKRQEALAAARLKMQEELNAQVEKHKEKLKQLEEEKRRQKIEMWDSMQEGKSYKGNAKKPQEEDS\nPGPSTSSVLKRKSDRKPLRGGGYNPLSGEGGGACSWRPGRRGPSSGGUG\n\n"
## 
## [[2]]
## [1] ">NP_001316384.1 glutathione peroxidase 1 isoform 5 [Homo sapiens]\nMCAARLAAAAAAAQSVYAFSARPLAGGEPVSLGSLRGKENAKNEEILNSLKYVRPGGGFEPNFMLFEKCE\nVNGAGAHPLFAFLREALPAPSDDATALMTDPKLITWSPVCRNDVAWNFEKFLVGPDGVPLRRYSRRFQTI\nDIEPDIEALLSQGPSCA\n\n"

# GETTING NAMES OF THE VECTORS "PROB1" AND "PROB2" IN THE SELENO_THINGY LIST.  
names(seleno_thingy) <- c("prot1", "prot2")

#Output
seleno_thingy

## $prot1
## [1] ">NP_060915.2 selenoprotein S isoform 1 [Homo sapiens]\nMERQEESLSARPALETEGLRFLHTTVGSLLATYGWYIVFSCILLYVVFQKLSARLRALRQRQLDRAAAAV\nEPDVVVKRQEALAAARLKMQEELNAQVEKHKEKLKQLEEEKRRQKIEMWDSMQEGKSYKGNAKKPQEEDS\nPGPSTSSVLKRKSDRKPLRGGGYNPLSGEGGGACSWRPGRRGPSSGGUG\n\n"
## 
## $prot2
## [1] ">NP_001316384.1 glutathione peroxidase 1 isoform 5 [Homo sapiens]\nMCAARLAAAAAAAQSVYAFSARPLAGGEPVSLGSLRGKENAKNEEILNSLKYVRPGGGFEPNFMLFEKCE\nVNGAGAHPLFAFLREALPAPSDDATALMTDPKLITWSPVCRNDVAWNFEKFLVGPDGVPLRRYSRRFQTI\nDIEPDIEALLSQGPSCA\n\n"

Elements of the list are accessed like this

seleno_thingy[[1]]

## [1] ">NP_060915.2 selenoprotein S isoform 1 [Homo sapiens]\nMERQEESLSARPALETEGLRFLHTTVGSLLATYGWYIVFSCILLYVVFQKLSARLRALRQRQLDRAAAAV\nEPDVVVKRQEALAAARLKMQEELNAQVEKHKEKLKQLEEEKRRQKIEMWDSMQEGKSYKGNAKKPQEEDS\nPGPSTSSVLKRKSDRKPLRGGGYNPLSGEGGGACSWRPGRRGPSSGGUG\n\n"

I’ll clean them with fasta_cleaner()

# first, make a copy of the list for storing the clean data
## I'm just going to copy over the old data
seleno_thingy_clean <- seleno_thingy


# HOW TO MAKE THIS MORE COMPACT? BY NOT MAKING A TEMPOROARY VARIABLE AND CODING THE FASTA_CLEANER() DIRECTLY.  
for(i in 1:length(seleno_thingy_clean)){
   clean_fasta_temp <- compbio4all::fasta_cleaner(seleno_thingy[[i]], parse = T)
  
  seleno_thingy_clean[[i]] <- clean_fasta_temp
}

Now the data looks like this HOW WOULD YOU DESCRIBE THIS? CLEANING THE LIST BY TAKING OUT ANY BACKLASH N AND HEADERS.

seleno_thingy_clean

## $prot1
##   [1] "M" "E" "R" "Q" "E" "E" "S" "L" "S" "A" "R" "P" "A" "L" "E" "T" "E" "G"
##  [19] "L" "R" "F" "L" "H" "T" "T" "V" "G" "S" "L" "L" "A" "T" "Y" "G" "W" "Y"
##  [37] "I" "V" "F" "S" "C" "I" "L" "L" "Y" "V" "V" "F" "Q" "K" "L" "S" "A" "R"
##  [55] "L" "R" "A" "L" "R" "Q" "R" "Q" "L" "D" "R" "A" "A" "A" "A" "V" "E" "P"
##  [73] "D" "V" "V" "V" "K" "R" "Q" "E" "A" "L" "A" "A" "A" "R" "L" "K" "M" "Q"
##  [91] "E" "E" "L" "N" "A" "Q" "V" "E" "K" "H" "K" "E" "K" "L" "K" "Q" "L" "E"
## [109] "E" "E" "K" "R" "R" "Q" "K" "I" "E" "M" "W" "D" "S" "M" "Q" "E" "G" "K"
## [127] "S" "Y" "K" "G" "N" "A" "K" "K" "P" "Q" "E" "E" "D" "S" "P" "G" "P" "S"
## [145] "T" "S" "S" "V" "L" "K" "R" "K" "S" "D" "R" "K" "P" "L" "R" "G" "G" "G"
## [163] "Y" "N" "P" "L" "S" "G" "E" "G" "G" "G" "A" "C" "S" "W" "R" "P" "G" "R"
## [181] "R" "G" "P" "S" "S" "G" "G" "U" "G"
## 
## $prot2
##   [1] "M" "C" "A" "A" "R" "L" "A" "A" "A" "A" "A" "A" "A" "Q" "S" "V" "Y" "A"
##  [19] "F" "S" "A" "R" "P" "L" "A" "G" "G" "E" "P" "V" "S" "L" "G" "S" "L" "R"
##  [37] "G" "K" "E" "N" "A" "K" "N" "E" "E" "I" "L" "N" "S" "L" "K" "Y" "V" "R"
##  [55] "P" "G" "G" "G" "F" "E" "P" "N" "F" "M" "L" "F" "E" "K" "C" "E" "V" "N"
##  [73] "G" "A" "G" "A" "H" "P" "L" "F" "A" "F" "L" "R" "E" "A" "L" "P" "A" "P"
##  [91] "S" "D" "D" "A" "T" "A" "L" "M" "T" "D" "P" "K" "L" "I" "T" "W" "S" "P"
## [109] "V" "C" "R" "N" "D" "V" "A" "W" "N" "F" "E" "K" "F" "L" "V" "G" "P" "D"
## [127] "G" "V" "P" "L" "R" "R" "Y" "S" "R" "R" "F" "Q" "T" "I" "D" "I" "E" "P"
## [145] "D" "I" "E" "A" "L" "L" "S" "Q" "G" "P" "S" "C" "A"

HOW WOULD YOU DESCRIBE THIS? EACH ELEMENT OF THE LIST IS A VECTOR OF CHARACTER DATA. CLASSIFICATION OF THE FIRST 1 OF THE NEW DATA, IDNFIYING THE DATA TYPE OF LIST, AND RETURNING A BOOLEAN VALUE OF LIST[1].

class(seleno_thingy_clean[[1]])

## [1] "character"

is(seleno_thingy_clean[[1]])

##  [1] "character"               "vector"                 
##  [3] "data.frameRowLabels"     "SuperClassMethod"       
##  [5] "character_OR_connection" "character_OR_NULL"      
##  [7] "atomic"                  "EnumerationValue"       
##  [9] "vector_OR_Vector"        "vector_OR_factor"

is.vector(seleno_thingy_clean[[1]])

## [1] TRUE

Make an dotplot

For old-times sake we can make a dotplot.
Now for a dotplot

WHAT AM I DOING HERE? TAKE EACH VECTOR IN THE LIST AND OUT IT INTO DIFFERENT VECTORS. ASSIGNING FIRST AND SECOND INDEX OF NEW, CLEAN LIST INTO TWO SEPARATE VECTORS.

prot1_vector <- seleno_thingy_clean[[1]]
prot2_vector <- seleno_thingy_clean[[2]]

We can dotplot like this

seqinr::dotPlot(prot1_vector,
                prot1_vector)

WHAT DID I DO DIFFERENTLY HERE? DIRECTLY INPUTTED THE INDEXES OF THE LIST INTO THE DOTPLOT FUNCTION INCTEAD OF VECTORS BEFOREHAND.

seqinr::dotPlot(seleno_thingy_clean[[1]],
                seleno_thingy_clean[[2]])

Pairwise alignment

dotPlot likes things in a single vector, but pairwiseAlignment like a single string of characters, so as always we have to process the data.

WHAT AM I DOING HERE? PASTING EVERYTHING IN THE VECTOR TOGETHER AND COLLAPSING THE OUTPUT INTO A SINGLE STRING. . WHAT DOES "" MEAN? "" MEANS A SPACE.

prot1_str <- paste(seleno_thingy_clean[[1]],sep = "", collapse = "")
prot2_str <- paste(seleno_thingy_clean[[2]],sep = "", collapse = "")

So now things look like this HOW WOULD YOU DESCRIBE THIS? THE OUT OF THE WOULD BE PASTED TOGETHER SEPARATED BY A SPACE.

prot1_str

## [1] "MERQEESLSARPALETEGLRFLHTTVGSLLATYGWYIVFSCILLYVVFQKLSARLRALRQRQLDRAAAAVEPDVVVKRQEALAAARLKMQEELNAQVEKHKEKLKQLEEEKRRQKIEMWDSMQEGKSYKGNAKKPQEEDSPGPSTSSVLKRKSDRKPLRGGGYNPLSGEGGGACSWRPGRRGPSSGGUG"

Protein alignments need a amino acid transition matrix, and we need to use data() to bring those up into active memory (VERY IMPORTANT STEP!)

data(BLOSUM50)

The alignment

align_out <- Biostrings::pairwiseAlignment(pattern = prot1_str, 
                              subject = prot2_str, 
                              type = "global",
                              gapOpening = -9.5,
                              gapExtension = -0.5)

What is this? THE RAW OUTPUT OF THE A GLOBAL PAIRWISE ALIGNMENT; NOT VERY INFORMATIVE ABOUT HOW THINGS LOOK IN VECTOR.

align_out

## Global PairwiseAlignmentsSingleSubject (1 of 1)
## pattern: MERQEESLSARPALETEGLRFLHTTVGSLLATYG...-----------------ACSWRPGRRGPSSGGUG
## subject: M---------------------------------...IDIEPDIEALLSQGPSCA----------------
## score: -160.2561

WHAT IS THIS? HOW IS IT DIFFERNT FROM THE LAST CHUNK? THIS IS DIRECTLY PRINTING THE GLOBAL PAIRWISE ALIGNMENT, ALIGN_OUT, USING THE PRINT_PAIRWISE_ALIGNMENT() FUNCTION. THE FULL PAIRWISE ALIGNMENT; SHOULD HAVE ALOT OF GAPS BECAUSE IT IS TWO RANDOM SEQUENCES.

compbio4all::print_pairwise_alignment(align_out)

## [1] "MERQEESLSARPALETEGLRFLHTTVGSLLATYGWYIVFSCILLYVVFQKLSARLRALRQ 60"
## [1] "M---------------------------------------C----------AARL----- 6"
## [1] " "
## [1] "RQLDRAAAAVEPDVVVKRQEALAAA--------RLKMQEELNAQVEKHKEKLKQLEEEKR 112"
## [1] "-----AAAA-------------AAAQSVYAFSAR-------------------------- 22"
## [1] " "
## [1] "RQKIEMWDSMQEGKSYKGNAKKPQEEDSPGPSTSSVLKRKSDRKPLRGGGYNPLSGE--- 169"
## [1] "--------------------------------------------PLAGG-------EPVS 31"
## [1] " "
## [1] "------------------------GGG--------------------------------- 172"
## [1] "LGSLRGKENAKNEEILNSLKYVRPGGGFEPNFMLFEKCEVNGAGAHPLFAFLREALPAPS 91"
## [1] " "
## [1] "------------------------------------------------------------ 172"
## [1] "DDATALMTDPKLITWSPVCRNDVAWNFEKFLVGPDGVPLRRYSRRFQTIDIEPDIEALLS 151"
## [1] " "
## [1] "-----A 227"
## [1] "QGPSCA 211"
## [1] " "

These are two randomly chosen sequences, so the alignment should be pretty dissimilar.

The score is negative, but on its own that IS VERY HARD TO INTERPRET OR TO UNDERSTAND.

score(align_out)

## [1] -160.2561

pid gives us A BETTER SENSE OF HOW WELL THE PAIRWIS ALIGNMENT MATCH UP.

pid(align_out)

## [1] 7.189542

Of course, pid can be calculated several ways BECAUSE IT USES DIFFERENT VALUES IN THE DEMONINATORS.

pid(align_out,type = "PID1")

## [1] 7.189542

pid(align_out,type = "PID2")

## [1] 91.66667

pid(align_out,type = "PID3")

## [1] 14.01274

pid(align_out,type = "PID4")

## [1] 12.71676