Cornelius Hunter is gloating over another study that disputes the notion of junk DNA [More Functions For “Junk” DNA, and More Functions For “Junk” DNA]. His article sounded interesting so I followed the link to the press release.
There was something about the press release that sounded suspicious and that prompted me to seek out the original published paper. Here it is with the abstract ...
Wong, J.J.-L., Ritchie, W., Ebner, O.A., Selbach, M., Wong, J.W., Huang, Y., Gao, D., Pinello, N., Gonzalez, M. and Baidya, K. (2013) Orchestrated Intron Retention Regulates Normal Granulocyte Differentiation. Cell 154:583-595. [PDF] [doi: 10.1016/j.cell.2013.06.052]
Intron retention (IR) is widely recognized as a consequence of mis-splicing that leads to failed excision of intronic sequences from pre-messenger RNAs. Our bioinformatic analyses of transcriptomic and proteomic data of normal white blood cell differentiation reveal IR as a physiological mechanism of gene expression control. IR regulates the expression of 86 functionally related genes, including those that determine the nuclear shape that is unique to granulocytes. Retention of introns in specific genes is associated with downregulation of splicing factors and higher GC content. IR, conserved between human and mouse, led to reduced mRNA and protein levels by triggering the nonsense-mediated decay (NMD) pathway. In contrast to the prevalent view that NMD is limited to mRNAs encoding aberrant proteins, our data establish that IR coupled with NMD is a conserved mechanism in normal granulopoiesis. Physiological IR may provide an energetically favorable level of dynamic gene expression control prior to sustained gene translation.
The authors found 86 genes expressed in mouse granulocytes where there were at least some transcripts that retained an intron. This could be due to mistakes in splicing but the authors prefer to think that intron retention is part of a regulatory step. The transcripts that retain an intron are degraded and this reduces the level of protein that would have been made if a properly spliced transcript had produced a functional mRNA.
It's an example of down-regulation, according to the authors. In most cases the intron-retaining transcripts make up only a few percent of the total transcripts but this is presumably enough to make a difference. In 25 of the genes, the aberrant transcripts are more that 25% of the total cytoplasmic transcripts.
There's nothing in the paper that mentions junk DNA.
Contrast this with the press release from Centenary Institute, Sydney Australia. I reproduce it below ...
How 'Junk DNA' Can Control Cell Development
Aug. 2, 2013 — Researchers from the Gene and Stem Cell Therapy Program at Sydney's Centenary Institute have confirmed that, far from being "junk," the 97 per cent of human DNA that does not encode instructions for making proteins can play a significant role in controlling cell development.
And in doing so, the researchers have unravelled a previously unknown mechanism for regulating the activity of genes, increasing our understanding of the way cells develop and opening the way to new possibilities for therapy.
Using the latest gene sequencing techniques and sophisticated computer analysis, a research group led by Professor John Rasko AO and including Centenary's Head of Bioinformatics, Dr William Ritchie, has shown how particular white blood cells use non-coding DNA to regulate the activity of a group of genes that determines their shape and function. The work is published today in the scientific journal Cell.
"This discovery, involving what was previously referred to as "junk," opens up a new level of gene expression control that could also play a role in the development of many other tissue types," Rasko says. "Our observations were quite surprising and they open entirely new avenues for potential treatments in diverse diseases including cancers and leukemias."
The researchers reached their conclusions through studying introns -- non-coding sequences which are located inside genes.
As part of the normal process of generating proteins from DNA, the code for constructing a particular protein is printed off as a strip of genetic material known as messenger RNA (mRNA). It is this strip of mRNA which carries the instructions for making the protein from the gene in the nucleus to the protein factories or ribosomes in the body of the cell.
But these mRNA strips need to be processed before they can be used as protein blueprints. Typically, any non-coding introns must be cut out to produce the final sequence for a functional protein. Many of the introns also include a short sequence -- known as the stop codon -- which, if left in, stops protein construction altogether. Retention of the intron can also stimulate a cellular mechanism which breaks up the mRNA containing it.
Dr Ritchie was able to develop a computer program to sort out mRNA strips retaining introns from those which did not. Using this technique the lead molecular biologist of the team, Dr Justin Wong, found that mRNA strips from many dozens of genes involved in white blood cell function were prone to intron retention and consequent break down. This was related to the levels of the enzymes needed to chop out the intron. Unless the intron is excised, functional protein products are never produced from these genes. Dr Jeff Holst in the team went a step further to show how this mechanism works in living bone marrow.
So the researchers propose intron retention as an efficient means of controlling the activity of many genes. "In fact, it takes less energy to break up strips of mRNA, than to control gene activity in other ways," says Rasko. "This may well be a previously-overlooked general mechanism for gene regulation with implications for disease causation and possible therapies in the future."
The published paper has nothing to do with junk DNA. Even if intron retention were a common mechanism of gene regulation (it is not), that would only account for about 100 base pairs per gene of additional sequence-dependant information. That's less than 0.1% of the genome.
This is a bad press release because it highlights information that is not in the published paper. The authors bear responsibility for press releases from their own institute that distort their published work. While they may not have written the press release, they presumably are quoted correctly and they should be aware of what's in the press release.
I wonder if they are willing to defend this press release as an accurate representation of their published work?
John Mattick and Jonathan Wells both believe that most of the DNA in our genome is functional. They do not believe that most of it is junk.
John Mattick and Jonathan Wells use the same arguments in defense of their position and they quote one another. Both of them misrepresent the history of the junk DNA debate and both of them use an incorrect version of the Central Dogma of Molecular Biology to make a case for the stupidity of scientists. Neither of them understand the basic biochemistry of DNA binding proteins leading them to misinterpret low level transcription as functional. Jonathan Wells and John Mattick ignore much of the scientific evidence in favor of junk DNA. They don't understand the significance of the so-called "C-Value Paradox" and they don't understand genetic load. Both of them claim that junk DNA is based on ignorance.
Dan Graur has a recent post on the phylogeny of placental mammals [The Root of the Placental Phylogenetic Tree: Are we Overlooking Something?]. He refers to a recent review in Molecular Biology and Evolution (MBE) that discusses various options. Graur believes that the question has been settled by examining transposon insertions.
But that's not the part that caught my attention. At the end of his post he says,
Finally, there is a small sentence in the Teeling and Hedges commentary that drove me up the wall: “The timing of the splitting event—approximately 100 Ma based on molecular clocks—is not in debate, at least among molecular evolutionists (Hedges et al. 1996…” Actually, dear Blair, it is. And whether you like it or not, both William Martin and I are fine molecular evolutionists.
The reference is to a paper by Dan Graur and Bill Martin—a formidable team that you want on your side because the alternative can be very embarrassing. You really, really don't want to mess with these guys.
We need more papers like this one.
Graur, D. & Martin, W. (2004) Reading the entrails of chickens: molecular timescales of evolution and the illusion of precision. TRENDS in Genetics 20:80-86 [doi: 10.1016/j.tig.2003.12.003] [PDF]
The enzyme L-glucono-γ-lactone oxidase is required for the synthesis of vitamin C. Humans cannot make this enzyme because the gene for this enzyme is defective [see Human GULOP Pseudogene]. The GenBank entry for this pseudogene is GeneID=2989. GULOP is located on chromosome 8 at p21.1 in a region that is rich in genes.
Here's a diagram that compares what is left of the human GULOP pseudogene with the functional gene in the rat genome.
Jerry Coyne thinks that the Beatles are the greatest rock group ever [Match this song!]. I'm pleased to announce that I agree with him on this point.
Jerry thinks that A Day in the Life is the best Beatles' song and that's where we part company. His second choice is Eleanor Rigby [Eleanor Rigby] and that's also one of my top ten.
We'll see what his other favorites are over the next few days. If he doesn't mention the very best song (IMHO) I'll correct him when he's finished.
Here's a short quiz for proponents of Intelligent Design Creationism. Let's see if you have been paying attention to real science. Please try to answer the questions below. Supporters of evolution should refrain from answering for a few days in order to give the creationists a chance to demonstrate their knowledge of biology and of evolution.
The bloggers at Evolution News & Views (sic) are promoting another creationist book [see Biological Information]. This time it's a collection of papers from a gathering of creationists held in 2011. The title of the book, Biological Information: New Perspectives suggests that these creationists have learned something new about biochemistry and molecular biology.
One of the papers is by Jonathan Wells: Not Junk After All: Non-Protein-Coding DNA Carries Extensive Biological Information. Here's part of the opening paragraphs.
James Watson and Francis Crick’s 1953 discovery that DNA consists of two complementary strands suggested a possible copying mechanism for Mendel’s genes [1,2]. In 1958, Crick argued that “the main function of the genetic material” is to control the synthesis of proteins. According to the “ Sequence Hypothesis,” Crick wrote that the specificity of a segment of DNA “is expressed solely by the sequence of bases,” and “this sequence is a (simple) code for the amino acid sequence of a particular protein.” Crick further proposed that DNA controls protein synthesis through the intermediary of RNA, arguing that “the transfer of information from nucleic acid to nucleic acid, or from nucleic acid to protein may be possible, but transfer from protein to protein, or from protein to nucleic acid, is impossible.” Under some circumstances RNA might transfer sequence information to DNA, but the order of causation is normally “DNA makes RNA makes protein.” Crick called this the “ Central Dogma” of molecular biology [3], and it is sometimes stated more generally as “DNA makes RNA makes protein makes us.”
The Sequence Hypothesis and the Central Dogma imply that only protein-coding DNA matters to the organism. Yet by 1970 biologists already knew that much of our DNA does not code for proteins. In fact, less than 2% of human DNA is protein-coding. Although some people suggested that non-protein-coding DNA might help to regulate gene expression, the dominant view was that non-protein-coding regions had no function. In 1972, biologist Susumu Ohno published an article wondering why there is “so much ‘ junk’ DNA in our genome” [4].
- Crick published a Nature paper on The Central Dogma of Molecular Biology in 1970. Did he and most other molecular biologists actually believe that "only protein-coding DNA matters to the organism?"
- Did Crick really say that "DNA makes RNA makes protein" is the Central Dogma or did he say that this was the Sequence Hypothesis? Read the paper to get the answer—the link is below).
- Is it true that, in 1970, the majority of molecular biologists did not believe in repressor and activator binding sites (regulatory DNA)?
- Is it true that in 1970 molecular biologists knew nothing about the functional importance of non-transcribed DNA sequences such as centromeres and origins of DNA replication?
- It is true that most molecular biologists in 1970 had never heard of genes for ribosomal RNAs and tRNAs (non-protein-coding genes)?
- If the answer to any of those questions contradicts what Jonathan Wells is saying then why do you suppose he said it?
Crick, F. (1970) Central Dogma of Molecular Biology. Nature 227:561-563. [PDF]
We've been in Copenhagen for a few days but today is the last day of our vacation. We fly to Iceland and Toronto in a few hours.
Here are some photos of Saint Petersburg. I was happy to visit the cruiser Aurora in the Neva river. I first read about its role in the Russian revolution when I was in high school.
The fourth photo shows a typical street scene in the city. You should be able to translate the sign (СТОП) under the stop lights if you were paying attention to my post from a few weeks ago.
The highlight of our Baltic cruise was the visit to Saint Petersburg, Russia. We hired a guide and driver to take us around to the various sites in Saint Petersburg and the outskirts. The Hermitage (Зрмитаж) museum is located on the banks of one of the main channels of the Neva river (Болъшая Нева). The first photo shows a view form across the river.
This is the old winter palace of the Russian Czars so the building itself is part of the history—like the Louvre in Paris.
The second photo is one of the spectacular views from inside the museum. Everyone says that you really need three days to see everything and I agree. However, our guide took us on a brief tour of the major highlights so we got a good impression in just three hours.
The last photo shows us getting into our van at the end of the visit. If you look closely, you’ll see the name of Ms. Sandwalk’s blog on the dashboard (click to embiggen).
We visited Helsinki, Finland, a few days ago (August 14, 2013). It was a rainy day. We spent most of our time shopping and walking around the old town.
We visited Stockholm yesterday and toured the city with my cousin Sharon and her husband Dennis. (That’s them with Ms. Sandwalk in the third photo.) Here are some photos of the Old Town including one of the Swedish Academy where I tried to put in a good word for all my readers.
We're celebrating our 45th wedding anniversary by taking a cruise in the Baltic. We were in Oslo, Norway on our anniversary day (August 9) where we met our friends Dag and Robin from graduate student days. They are als0 marride 45 years so we celebrated with champagne at their house. More about that later.
The University of Rostock was founded in 1419. It’s said to be the oldest university in the Baltic Sea area. The main university building is a prominent landmark in Rostock but I was more interested in the Zoology building off to the side.
Looks like I just missed an important conference. Does everyone know who Willi Hennig is?
Yesterday our boat stopped at the habor in Warnemünde, Germany. There was a lot of activity of the quay in Warnemünde because a number of tall ships were in the harbor.
We took the train to the medieval town of Rostock—a key port in the Hansiatic League (Hansa=guilds). The architecture was similar to that in other leading cities of the Hansiatic League, notably Bruges.
We've been on this boat for three days and we'll be on it for another 8 days as we cruise the Baltic Sea. Internet access costs 70 cents ($0.75 US) per minute so posts will be short and infrequent.