Last Sun­day I was on a pan­el at the Amer­i­can Soci­ety for Micro­bi­ol­o­gy meet­ings.  I’ll post a slide­cast of the talk in a few days, and get into the top­ic of the pan­el in more detail then. 

Since I was pre­sent­ing, I got a free pass to the rest of the con­fer­ence, which was fas­ci­nat­ing.  I’m a mac­ro­bi­ol­o­gist by train­ing and by avo­ca­tion; I worked one sum­mer in a fruit fly lab study­ing Wol­bachia infec­tions, and quick­ly moved on to ani­mals one can see and touch.  So I was curi­ous to find out what micro­bi­ol­o­gists spend their time talk­ing about.

What struck me most was how few of the tech­niques peo­ple were using would have exist­ed, or at least been wide­ly avail­able, when I was in grad school.  Many of the talks I attend­ed involved tech­niques in metage­nomics, a sub­ject I had to do some quick research on from the audi­ence just to fol­low along.

Metage­nomics takes the sort of DNA sequenc­ing that crime labs use for DNA fin­ger­print­ing, and it amps it up.  Rather than try­ing to iden­ti­fy a sin­gle indi­vid­ual or species from its unique DNA, metage­nom­ic tech­niques let researchers grab a sam­ple with hun­dreds or thou­sands of micro­bial species.  They’ll take a drop of water, or a swab from the side of a hoatz­in’s stom­ach, make lots of copies a pre-deter­mined stretch of DNA present in all of the species present, sequence all of those stretch­es, and then com­pare them to know species to assess the diver­si­ty with­in that droplet.

The amount of data which comes from a droplet can be stag­ger­ing.  Most remark­ably, most of the stud­ies I saw involved doing that analy­sis hun­dreds of times.  In one case, researchers took swabs of bac­te­ria from dozens of babies mouths, from behind their ears, and from their poop, to help them track how the micro­bial world inside and around babies change after birth, and to trace the effects of antibi­ot­ic treat­ments on that world.  To do that, they had to take three such sets of sam­ples from every baby, once a month, for years.  Each month, each baby gave them 9 sam­ples, the moth­er con­tributed sev­er­al more, and the team con­duct­ed a metage­nom­ic sur­vey of bac­te­r­i­al diver­si­ty on each of them. Each of those nine analy­ses per baby, per month, prob­a­bly involved more genom­ic data than was rep­re­sent­ed by all the papers in a giv­en vol­ume of The Jour­nal of Mam­mal­o­gy from ten years ago.  And these researchers did that for dozens of babies, every month, for years.

In anoth­er case, researchers curi­ous about the unusu­al diges­tive sys­tem of the hoatzin per­formed metage­nom­ic analy­ses to find out how bac­te­ria work in the unique foregut that lets the bird break down leaves.  So they took sam­ples of bac­te­ria from the wall of the gut, oth­ers from the midst of the mass of digest­ing leaves, and oth­ers from fur­ther back in the gut.  Anoth­er researcher used metage­nomics to iden­ti­fy new kinds of virus­es affect­ing the microbes of Yel­low­stone’s hot­springs. Anoth­er used these tools to track antibi­ot­ic resis­tance in pets.  Thanks to these tools, the researchers can exam­ine bac­te­r­i­al ecosys­tems on a scale unimag­in­able only a few years ago.  They can see how the bac­te­ria on your hands and those in your gut and your nose com­pare, and see how those bac­te­r­i­al ecosys­tems com­pare to those in uncon­tact­ed pop­u­la­tions in the Ama­zon, and how those bac­te­ria are passed on to your chil­dren, or to and from your pets. They can under­stand how dif­fer­ent species of microbes relate to one anoth­er in ways that were nev­er pos­si­ble before, chang­ing how sci­en­tists think about this invis­i­ble world.

It’s unfath­omable how each of these authors could stand on stage and not be struck dumb by how quick­ly their field has transformed. 

And it did­n’t stop there.  Metage­nomics involves look­ing at a short chunk of DNA, one vari­able enough to mark unique bac­te­r­i­al lin­eages, but not so large as to be imprac­ti­cal to sequence.  But in many of the talks, researchers indi­cat­ed that the fol­lowup research would involve sequenc­ing genomes of some of the inter­est­ing bugs they’d found.  Some­times they were doing this to iden­ti­fy pre­vi­ous­ly unknown species, but oth­er times they just want­ed to iden­ti­fy antibi­ot­ic resis­tance and see how the antibi­ot­ic resis­tance of sev­er­al strains of a sin­gle bac­te­r­i­al species compared.

Again, these researchers tossed off the idea of run­ning whole-genome sequences – sequences, plur­al – as if it was a chore to be assigned to a par­tic­u­lar­ly dull new grad stu­dent.  The first bac­te­r­i­al genome was sequenced in 1995, and it was pub­lished in Sci­ence and giv­en the hon­or of the cov­er illus­tra­tion.  Less than 20 years lat­er, it’s routine.

The rea­sons for this trans­for­ma­tion are fair­ly straight­for­ward.  Over the last 5 years, the cost of sequenc­ing a genome has dropped pre­cip­i­tous­ly, far faster than com­put­er speeds increase (Moore’s law says com­put­er speeds dou­ble every 18 months):

That graph, from the Nation­al Human Genome Research Insti­tute, shows how what was once a mas­sive under­tak­ing, an effort that involved the com­bined efforts of thou­sands of peo­ple around the world, new inven­tions and years of sus­tained effort, now costs less than $10,000, and can be com­plet­ed in a mat­ter of hours.

Before I went to the con­fer­ence, I joked with peo­ple that I’d be sure to bring my micro­scope with me.  Boy would that have marked me as an old fogey.