Now, researchers from
the University of
Rochester
The notorious Y chromosome
Y chromosomes are sex
chromosomes in males that are transmitted from father to son; they can be
important for male fertility and sex determination in many species. Even though
fruit fly and mammalian Y chromosomes have different evolutionary origins, they
have parallel genome structures, says Larracuente, who co-authored the paper
with her PhD student Ching-Ho Chang. “Drosophila melanogaster is a
premier model organism for genetics and genomics, and has perhaps the best
genome assembly of any animal. Despite these resources, we know very little
about the organization of the Drosophila Y chromosome because most of
it is missing from the genome assembly.”
That’s in part because
most Y chromosomes do not undergo standard recombination. Typically, genes from
the mother and father are shuffled—or, “cross over”—to produce a genetic
combination unique to each offspring. But the Y chromosome does not undergo
crossing over, and, as a result, its genes tend to degenerate, while repetitive
DNA sequences accumulate.
Sequencing vs. assembling
Each chromosome is made
up of DNA. When mapping a genome, traditional sequencing methods chop up strands
of DNA and read—or sequence—them, then try to infer the order of those
sequences and assemble them back together.
But, “there is a
difference between sequencing a genome and assembling a genome,” Larracuente
says. There are so many repetitive strands on the Y chromosome that the pieces
tend to look the same. It is difficult, therefore, to figure out where they
come from and how to reassemble the strands—like trying to put together a
puzzle when all of the pieces are exactly the same color. “When we try to take
those bits of DNA and assemble them to see what the chromosome looks like, we
can’t fill in some of those gaps. We might have the sequence, but we don’t know
where it goes.”
A different type of recombination
Using sequence data
generated by new technology that reads long strands of individual DNA
molecules, Chang and Larracuente developed a strategy to assemble a large part
of the Y chromosome and other repeat-dense regions. By assembling a large
portion of the Y chromosome, they discovered that the Y chromosome has a lot of
duplicated sequences, where genes are present in multiple copies. They also
discovered that although the Y chromosome does not experience crossing over, it
undergoes a different type of recombination called gene conversion. While
crossing over involves the shuffle and exchange of genes between two different
chromosomes, gene conversion is not reciprocal, Larracuente says. “You don’t
have two chromosomes that exchange material, you have one chromosome that
donates its sequence to the other part of the chromosome” and the sequences
become identical.
The Y chromosome has
therefore found a way to maintain its genes via a process different from
crossing over, Larracuente says. “We usually think of the Y chromosome as a
really harsh environment for a gene to survive in, yet these genes manage to
get expressed and carry out their functions that are important for male
fertility. This rampant gene conversion that we’re seeing is one way that we
think genes might be able to survive on Y chromosomes.”
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