Editor’s Note – This essay was subsequently published as:
Dillon, R.T., Jr. (2019c) Pleurocera clavaeformis in the Mobile Basin? Pp 179 - 189 in The Freshwater Gastropods of North America Volume 3, Essays on the
Prosobranchs. FWGNA Press, Charleston.
This is the final installment of my five-part series [1] reviewing
an excellent recent paper by Nathan Whelan and Ellen Strong [2] on DNA sequence
variation within and among an assortment of pleurocerid populations sampled
from North Alabama. The most important
contributions made by Whelan & Strong will turn out to be their large and
fine data set on mitochondrial superheterogeneity, and their demonstration that
no morphological characters seem to correlate with it, putting to rest the hypothesis
of cryptic speciation. Their paper also sheds
new light on evolutionary relationships among the pleurocerid populations of the
Mobile and Tennessee drainages, if one is able to contextualize the information
they have developed. Such will be our
business in the essay that follows.
Whelan and Strong sampled five populations of Leptoxis picta
(which they identified as L. “ampla”) from tributaries of the Alabama River
draining south into the Mobile Basin and one population of the widespread and
well-studied Leptoxis praerosa sampled from a tributary of the Tennessee River,
draining west. Despite the strikingly
high incidence of mitochondrial superheterogeneity demonstrated by the five
picta populations, the praerosa population remained genetically distinctive,
demonstrating about 13% CO1 sequence divergence from modal picta. This observation dovetailed neatly with the (nuclear) histone H3 sequence data also developed by Whelan & Strong, and with a much larger (9 locus, 11
population) allozyme data set published by Chuck Lydeard and myself in 1998 [3],
all of which combined to strongly reinforce the validity of the specific
distinction between L. picta populations inhabiting the Mobile Basin and L.
praerosa inhabiting the Tennessee.
But such did not seem to be the case with the five
populations Whelan & Strong identified as “Pleurocera prasinata” from
tributaries of the Mobile Basin, when compared with the population they
identified as “Pleurocera pyrenella” from a tributary of the Tennessee. As we brought our essay of 3May to a close,
we noticed that the histone H3 data did
not return any evidence of a genetic distinction between any of the six
Pleurocera populations whatsoever.
And indeed the larger dataset developed by Whelan &
Strong on CO1 sequence divergence did
not demonstrate a distinction between any of the six North Alabama Pleurocera
populations either. The gene tree above shows
that the modal CO1 haplotype sequenced from the Tennessee “pyrenella”
population (“clade 6”) was just 2% different from both the modal prasinata
clade 8 and the first-runner-up prasinata clade 7 [4]. But the gene tree below shows that CO1 sequence
divergence within the Tennessee “pyrenella” population ranged up to 8% [5].
Nor indeed is there any significant morphological
distinction among Whelan & Strong’s six Pleurocera populations. Last month we reviewed the general topic of
ecophenotypic plasticity in shell morphology, as it applies to the Pleurocera
populations of North Alabama. It was our
strong impression that the Tennessee drainage Pleurocera population sampled by
Whelan & Strong, referred by them to “Pleurocera pyrenella,” was
misidentified. In fact, Whelan &
Strong’s Figure 7, reproduced in last month’s post, suggested that all six North Alabama Pleurocera
populations are morphologically indistinguishable from Pleurocera clavaeformis.
Now here is the second-most amazing revelation to come from the
Whelan & Strong’s remarkable data set [6].
In order to explain the amazingness of this revelation, however, I’ll
need to digress a bit into the basic mechanics of the NCBI GenBank. And backtrack to 2011. So bear with me.
Among the most useful and powerful tools on the GenBank menu
is “BLAST,” the “Basic Local Alignment Search Tool.” A user can call up any sequence from the
database, say for example KT164088, the first CO1 sequence Whelan & Strong
listed in their Table 1 for modal CO1 clade 8 of “Pleurocera prasinata.” And then simply click the BLAST button
(optimized for more dissimilar sequences), and wait a minute or two. And the BLAST tool will return the (default)
100 sequences in GenBank most similar to KT164088. Amazing.
I never thought I would live to see the day.
So W&S uploaded all 5 x 20 = 100 of their “prasinata”
CO1 sequences to GenBank, plus all 20 of their “pyrenella” CO1 sequences, for
a total of 120 CO1 sequences from North Alabama Pleurocera [7]. You might think that if you simply picked a
representative sequence from the modal “prasinata” CO1 cluster and hit the
BLAST button, the search tool would return 100 other North Alabama Pleurocera
sequences, wouldn’t you? But this is not
the case. Down toward the bottom of the
big list you will get if you perform the experiment I have outlined above, at
about 95% similarity with KT164088, you will begin to see a sprinkling of P.
clavaeformis from East Tennessee.
At this point in the history of the FWGNA Blog, I have
referred to my 2011 paper in Malacologia – the one that synonymized Goniobasis
& Elimia under Pleurocera [8] – so often that I imagine you all are sick of
it [9]. That was an allozyme paper,
involving 9 populations of P. clavaeformis from East Tennessee, 4 control populations
of P. simplex, and a pair of carinifera/vestita populations from North Georgia,
more about which later. The summer that
paper was published, John Robinson and I sequenced single individual CO1
haplotypes from each of those same 15 populations, in connection with an oral
presentation we were planning for the 2011 AMS meeting in Pittsburgh. We uploaded those 15 sequences to GenBank
promptly, although our results were not ultimately published until quite
recently [10]. The gene tree looks like
this:
Now here’s a mental exercise for you. Imagine Figure 3 above rotated 180
degrees. It will actually fit almost
like a lock-and-key into the top half of Whelan & Strong’s Figure 2, like
this:
The modal CO1 sequence that Dillon & Robinson obtained
from 6 of our 9 P. clavaeformis populations in East Tennessee is approximately
95% similar to the modal “prasinata/pyrenellum” sequence that W&S obtained
from North Alabama. And in fact, one of
our outlying East Tennessee sequences (JF837315) is approximately 95% similar
to a bunch of the outlying North Alabama sequences. The bottom line is that all six North Alabama Pleurocera populations are genetically
indistinguishable from East Tennessee P. clavaeformis.
I first preached a series of sermons on this topic back in
2009 [11], but The Spirit has moved me into the pulpit again. The evolutionary relationships between the
malacofaunas of the Tennessee River and the Mobile Basin are much closer than
anyone has ever realized.
Nineteenth-century taxonomic tradition has always held that the two
pleurocerid faunas are completely disjoint, sharing no species whatsoever. But the shell morphological intergradation we
see in East Tennessee from acutocarinata to clavaeformis to unciale to curta is
strikingly parallel to the intergradation from carinifiera to vestita to
praesinata to foremani observed in the Mobile Basin. That was my rationale for analyzing a
carinifera/vestita set from North Georgia together with the three sets of
acutocarinata/clavaeformis/unciale I sampled from East Tennessee in 2011. It seemed possible to me that all 11
populations might prove conspecific.
On the basis of the ten polymorphic allozyme-encoding loci I
analyzed in 2011, the genetic relationship between the two North Georgia
populations and the nine East Tennessee populations was ambiguous. As were the CO1 results I subsequently obtained
with John Robinson, reproduced above.
Ultimately I decided to refer to the entire basket-full of
Tennessee/Mobile Basin populations sharing this similar, slippery shell
morphology as the “carinifera group,” and set the matter aside [12, 13].
The results of Whelan & Strong have reawakened the
issue, and brought it roaring back to the fore.
In North Alabama, apparently Pleurocera “prasinata” of the Mobile Basin
is genetically and morphologically indistinguishable from Pleurocera clavaeformis
of the Tennessee. This is big news [14].
Science is the construction of testable hypotheses about the
natural world. So I will concluded my
long, rambling series of essays on the North Alabama Pleuroceridae with some
science. Pleurocera prasinata populations
are moderately common in the main Coosa River and in scattered larger
tributaries downstream from the North Georgia populations of P. carinifera and
P. vestita I sampled for my 2011 paper [15].
I hypothesize that Coosa River populations of P. prasinata are more
genetically similar to North Georgia carinifera and vestita than they are to
the Cahaba populations of P. prasinata sampled by Whelan & Strong. I challenge any of my colleagues with
research interests in the Alabama Pleuroceridae to test my hypothesis, using
any genetic tools at their disposal.
We’ll be standing by.
Notes:
[1] Previous installments in this series:
- Mitochondrial Superheterogeneity: What we know [15Mar16]
- Mitochondrial Superheterogeneity: What it means [6Apr16]
- Mitochondrial Superheterogeneity and Speciation [3May16]
- The Shape-shifting Pleurocera of North Alabama [2June16]
[3] Dillon, R.T., and C. Lydeard (1998) Divergence among
Mobile Basin populations of the pleurocerid snail genus, Leptoxis, estimated by
allozyme electrophoresis. Malacologia.
39: 111-119. [PDF]
[4] The estimated 2% sequence divergence values shown in
Figure 1 were obtained by blasting a randomly chosen modal (clade 6) pyrenella
CO1 sequence, KT164127, against randomly-chosen Clade 7 sequence KT164125 and
Clade 8 sequence KT164088.
[5] The estimate of 8% mtDNA sequence shown in Fig 2 above
was obtained by blasting modal (clade 6) CO1 sequence KT164127 against clade 3 CO1
sequence KT164138.
[6] The first-most amazing thing is CO1 sequence KT163940,
that single blue dot showing at Red-star-14 in the final figure of my May post.
[7] Well, to be precise, one individual was excluded by
misidentification, and no CO1 sequence was obtained for 6 others. So 113 North Alabama Pleurocera CO1
sequences, to be precise.
[8] Dillon, R. T. (2011)
Robust shell phenotype is a local response to stream size in the genus
Pleurocera (Rafinesque 1818). Malacologia
53: 265-277. [PDF]
[10] Dillon, R. T. Jr, and J. D. Robinson (2016) The hazards of DNA barcoding, as illustrated
by the pleurocerid gastropods of East Tennessee. Ellipsaria 18(1): 22-24. [PDF]
[11] My 2009 series on genetic relationships in the Mobile
Basin Pleuroceridae:
- Mobile Basin I: Two pleurocerids proposed for listing [24Aug09]
- Mobile Basin II: Leptoxis lessons [15Sept09]
- Mobile Basin III: Pleurocera puzzles [12Oct09]
- Mobile Basin IV: Goniobasis WTFs [13Nov09]
[13] So following the logic above, I seriously considered
entitling the present essay “Pleurocera carinifera in the Tennessee Basin,” not
“Pleurocera clavaeformis in the Mobile Basin.”
But ultimately I decided that this entire topic is already sufficiently
complex and obscure. There aren’t five people
in the world who know what I mean when I say “Pleurocera clavaeformis,” and if
I swapped over to Pleurocera carinifera, I’d confuse even those.
[14] Here’s another mental exercise. In what sense of the adjective “big” is this
news big?