Crowdsourcing HIV Research 52
biolgeek writes "In recent years, HIV has been managed with a collection of therapies. However, the virus will likely evolve around these drugs, making it crucially important to get a better understanding of the virus itself. An important step in understanding the virus is to get a handle on its genetic blueprint. William Dampier of Drexler University is taking a novel approach to this research by crowdsourcing his problem. He is hosting a bioinformatics competition, which requires contestants to find markers in the HIV sequence that predict a change in the severity of the infection (as measured by viral load). So far the best entry comes from Fontanelles, an HIV research group, which has been able to predict a change in viral load with 66% accuracy."
Interesting approach. (Score:3, Interesting)
Can't help but wonder, though, if they're trying to solve the wrong problem. There's research out that suggests that virus-related cancers are exploiting what are effectively a small set of security holes in the way DNA handles the "junk" portions. HIV is a retrovirus, IIRC, which also means it installs itself into the DNA. The first line of attack I'd have thought of, based on those two pieces of information alone, would be to see if the SAME security holes are responsible for both the virus-caused cancers and HIV breaking into the DNA. If there is a common attack vector, across multiple viruses, then that attack vector becomes far more interesting than the specifics of each virus.
Assuming the attack vector cannot actually be patched in mainstream cells, to fix the flaw, then perhaps it can be fixed in T-Cells, which are essentially disposable and it doesn't matter a whole lot if they're non-standard. HIV crashes the immune system through a massive DDoS attack via the immune system itself, by using the T-Cells. If the T-Cells are closed to that specific attack, then the virus can mutate all it likes but it can't crash the immune system. IF it is invariant across multiple viruses, then it's likely invariant across all of HIV strains. Merely preventing a DDoS on the immune system should massively slow the virus down and improve the chances of additional treatments actually ridding the body of the virus.
The ideal would be to fix the security hole in total, for all cells. I'm not sure that's possible, as evolution has required the mechanism to inject new code into the DNA strands. Indeed, a lot of evolution would be impossible without such a mechanism, and you can't exactly install X.509 certificates into all harmless or potentially beneficial RNA and DNA sources on the off-chance they need to integrate. Besides, cell defenses don't usually include SSL. The best I think you can probably do is bio-engineer a new DNA strand, which you can install in an organelle (organelles are just places where cells used to have DNA before all the useful bits were pushed over into the nucleic DNA), which provides some sort of Intrusion Detection System. As I see it, you've two options - a honey-pot (an extra-vulnerable DNA strand that causes the whole cell to self-destruct if infected by a retrovirus), or a Tripwire-like IDS that looks for mutations in any given strand of nucleic DNA =and= monitors for virus-production. If both conditions are satisfied (ie: it's not a benign insert, but a malign one), then the strand is broken up.
Again, not sure if this is remotely possible. Sure, there are enzymes which break up DNA - they're used all the time for sequencing, as you can't sequence long strands. But to identify a malign region in the DNA =and= have the enzyme only break the DNA at that point =and= have this done in a way that won't cause the end result to do strange and undesirable things -- that's going to be tough.
So if this approach is so tough, why go for it? Because researchers have tried targeting the virus directly and have failed utterly. Deactivating it only results in it reactivating itself, making vaccines extremely hard to produce. When they are produced, the virus has mutated and the vaccine is useless. In other cases, the virus has even used the immune response to hijack more immune system cells, so as to spread faster. It also mutates so fast that what worked one week won't work the next. Direct attacks have no serious shelf-life and just won't work.
That leaves indirect attacks. To beat the mutation problem, you need some aspect of the virus that will never change. If one such aspect is the mechanism for breaking into nucleic DNA and inserting rogue sequences, controlling that entry-point will not only beat AIDS, but it will beat some cancers too. Since uncontrolled entry into DNA is why some gene therapies cause cancers, controlling the entry point will also be critical to gene therapy being successful for a wide range of conditions.
Thus, this is the obvious place to focus on. Ign
Re:Wow (Score:2, Interesting)
I find this kind of stuff amazingly ironic. We're going to burn more fuel and produce more cancer-causing emissions so that we can produce more CPU cycles to fight illness. I don't know about you but my operating systems send HLT instructions to my processors when they're idle.