Editor's Note. This essay was subsequently published as: Dillon, R.T., Jr. (2019b) The heritability of shell morphology in Physa H^2 = 0.819! Pp 207-211 in The Freshwater Gastropods of North America Volume 2, Essays on the Pulmonates. FWGNA Press, Charleston.
That’s the headline in the most recent edition of PLoS ONE, fresh on the news stands Monday morning. Read all about it from the link below [1].
That’s the headline in the most recent edition of PLoS ONE, fresh on the news stands Monday morning. Read all about it from the link below [1].
To place this remarkable statistic in perspective,
animal breeders typically consider heritability in the range of 0.2 – 0.4 to be
moderate, and heritabilities above 0.4 to be high. The heritability of egg production in poultry
is approximately h^2 = 0.10, milk yield in cattle about h^2 = 0.35, and weight
gain per day in swine h^2 = 0.40 [2]. My
colleague Stephen Jacquemin and I reviewed scores of estimates for the
heritability of various aspects of gastropod shell morphology (marine, freshwater
and terrestrial) in 14 peer-reviewed papers published since 1965, finding but
one single value greater than h^2 = 0.819 ever reported [3]. For freshwater gastropods, the highest value
reported to date (in a much smaller literature!) is h^2 = 0.30 [4]. How did Stephen and I arrive at our an
eye-popping result?
I should imagine that most of my readership will
be familiar with the shell morphology of the cosmopolitan invasive Physa acuta,
figured at right above. The shell of
Physa carolinae, the recently-described [5] inhabitant of southeastern coastal
plains figured at left, is distinctly more slender and fusiform by
comparison. The two species hybridize
readily, although the F1 are almost entirely sterile [6].
Stephen and I crossed four pairs of acuta, four
pairs of carolinae, and four axc hybrid pairs, rearing all 24 parent animals in
standard conditions to age 20 weeks. We then
raised 5 F1 progeny from each of these 12 crosses to age 20 weeks in identical
conditions. And for the entire set of 24
parents plus 60 F1 offspring we took six “classical” linear measurements of the
shell and digitized 11 landmark points.
The figure below shows the regression of the simple
shell length of the 12 sibships on their mid-parent values, Y = 0.429x + 0.295. The slope of the regression line estimates
the narrow-sense heritability of shell length in Physa as conventionally
measured, h^2 = 0.429 (s.e. = 0.139), significant at the (adjusted) 0.008 level.
Stephen and I performed similar calculations for our five other simple linear measurements, the first and second principal
components extracted from both the correlation and covariance matrices of these
measurements, scores on the first three relative warp axes from a geometric
analysis, and centroid size. The heritability
estimates for all 14 of these variables, with their p-values adjusted for
multiple comparisons, are shown in Table 2 of our paper downloadable below. And our headline estimate of h^2 = 0.819 (s.e.
= 0.073) is for variance on the first relative warp axis (RWA1).
Now if overall “shell size” is defined as the summed
distance from each of the 11 landmarks to their joint centroid, variance on
RWA1 is significantly correlated with shell size at the 0.001 level. So are almost all of the other 12 variables
we measured (see Table 1 of our paper).
This implies that, as strikingly heritable as variance on RWA1 most
certainly is, such variance may not be especially useful for inferring
evolutionary relationships among natural populations of freshwater gastropods,
which are inevitably composed of mixed ages.
Thus the second-most interesting result reported
in the paper by myself and my buddy Stephen may not be the heritability of
RWA1, but the h^2 = 0.312 (s.e. = 0.123) we estimated for score on RWA2. This variance is not apparently correlated with
overall shell size, and hence might (with some disclaimers) find application to
populations of freshwater gastropods sampled from the wild.
And what might our first-most interesting result
be? I think it is the fact that Stephen and I
were able to uncover any significant heritability in any aspect of freshwater
gastropod shell morphology whatsoever.
The phenomenon of ecophenotypic plasticity is so pervasive in
populations of freshwater gastropods as to warrant a separate heading in the blog
index at right above, with 13 entries to date. My stack of peer-reviewed papers documenting plasticity
of shell morphology in freshwater snail populations stands 35 deep. So quoting directly from the concluding
paragraph of this our most recent addition to the literature, “Against such a
background, the results reported in the present work can be viewed as providing
a small measure of balance.”
Notes
[1] Dillon, R. T., Jr. & S. J. Jacquemin
(2015) The heritability of shell
morphometrics in the freshwater pulmonate gastropod Physa. PLoS ONE 10(4): e0121962. [html] [pdf]
[2] Falconer, D. S. & T. F. C. Mackey (1996)
Introduction to Quantitative Genetics, Fourth Edition. Essex: Pearson Education Ltd.
[3] Conde-Padin, P. et al (2007) Genetic variation for shell traits in a
direct-developing marine snail involved in a putative sympatric ecological speciation
process. Evolutionary Ecology 21:
635-650.
[4] Chaves-Campos, Coghill, Al-Salamah, DeWitt
& Johnson (2012) Field heritabilities and lack of correlation of snail form
and anti-predator function estimated using Bayesian and maximum likelihood
methods. Evol. Ecol. Res. 14: 743-755.
[5] TRUE CONFESSIONS: I described a new species.
[7Apr10]
[6] Wethington, A.R., J. Wise, and R. T. Dillon
(2009) Genetic and morphological characterization of the Physidae of South
Carolina (Pulmonata: Basommatophora), with description of a new species. The
Nautilus 123: 282-292. [pdf]
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