# How to use recursion to find longest valid DNA sequences?

I'm new to Python and I have a project that I just cannot understand. It requires using recursion to find the longest valid DNA sequence when given two strands. I am given a file called dna.txt. The first line of the file contains a number that is how many pairs of DNA strands there will be. Then the rest of the lines are strings of DNA. My job is to look at each pair of strands individually and find the longest valid DNA sequence and write it into a new file called dnaresults.txt. If this was to be done through iteration I'm fairly confident I could handle it. But the project requires that I use recursion to a)find valid DNA sequences and b)find the longest DNA pairs. I understand recursion on a very basic level (Fibonacci, rolling sum, etc.) but I just cannot wrap my head around how to apply it in this situation.

For example, the input file will look like follows:

``````3
GAAGCTCG
CCTCGGGA
AAATTT
GGGCCC
CTCTAGGAC
GAGTACCTG
``````

and I am required to output this to a new file:

``````DNA sequence pair 0:
AGC
TCG

DNA sequence pair 1:
No matches found

DNA sequence pair 2:
GGAC
CCTG
``````

This is what I have tried so far. I can use the number to determine how many times to execute my loop. I can get the pair of strands separated and in their own variable. But once the time has come to evaluate and compare them I'm stumped because I don't understand how to use recursion in this case.

``````def main():
numOfPairs = int(dnaFile[0])

for i in range(0, numOfPairs*2, 2):
firstStrand = str(dnaFile[i+1])
secondStrand = str(dnaFile[i+2])
firstStrand.upper()
secondStrand.upper()
``````

So that's where I'm at right now. If anyone could point me in the right direction with the recursion that would be amazing. I'm really just so clueless as to how I'm supposed to use recursion to compare the DNA strands while also storing and returning only the longest one. Thanks in advance!

Edit: My apologies. A DNA sequence is valid when an A on one strand is paired with a T on another (and vice versa) and a G on one strand is paired with a C on another (and vice versa).

``````ACTGTC
TGACAG
``````

That is a valid sequence because every pair is A-T or G-C.

``````ACTGTC
GCACTA
``````

That is not a completely valid sequence because not every pair is A-T or G-C. Only the 3rd and 4th pairs are valid (TG and AC).

• I could look it up but to make our lives easier can you add what makes the DNA valid. Apr 22, 2019 at 19:54
• @Error-SyntacticalRemorse Corresponding basepairs: A goes with T, and G goes with C. Apr 22, 2019 at 19:57
• Can we assume that you only need to write a recursive function that, given two strands of DNA, returns the longest matching subsequences? That's bad enough, but requiring recursion to iterate over the file would just be asinine. Apr 22, 2019 at 19:58
• This question isn't a good one for recursion it can be done using a linear solution. This type of problem would just take up a large amount of stack. Apr 22, 2019 at 20:03
• Do you have to consider shifts? Given `ACTGC` and `GACGT`, would the answer be no match or `CTGC`/`GACG`? Apr 22, 2019 at 20:22

Recursion for this type of problem uses a stupid amount of stack and is significantly slower than using built in data structures that take linear time and constant space. I understand recursion is needed because that is your problem but I still feel like I should say that.

Here is a recursive solution:

First a function to check for valid pairs:

``````def valid_pair(c1, c2):
pairs = {
'G': 'C',
'C': 'G',
'A': 'T',
'T': 'A'
}
return pairs[c1] == c2
``````

Now the recursion method:

``````def compare_strands(s1, s2, count=0, result=["", ""]):
if not s1 or not s2: # base case
return count, result
# If it is not a valid pair
if not valid_pair(s1[0], s2[0]):
old_max, old_str = count, result
new_max, new_str = compare_strands(s1[1:], s2[1:], 0, ["", ""])
if new_max < old_max:
new_max = old_max
new_str = old_str
else:
temp_result = []
temp_result.append(result[0] + s1[0])
temp_result.append(result[1] + s2[0])
# result[1] += s2[0]
count = count + 1
new_max, new_str = compare_strands(s1[1:], s2[1:], count, temp_result)
return new_max, new_str
``````

Testing:

``````with open('dna.txt', 'r') as f:
for i in range(size):
print(compare_strands(strand1, strand2))
``````

Output:

``````(3, ['AGC', 'TCG'])
(0, ['', ''])
(4, ['GGAC', 'CCTG'])
``````

Edit: To write to file.

``````with open('dna.txt', 'r') as f:
for i in range(size):