Article
Ecological divergence and hybridization of Neotropical Leishmania parasites
Registration in:
VAN DEN BROECK, Frederik et al, Ecological divergence and hybridization of Neotropical Leishmania parasites. PNAS, v. 117, n. 40, p. 25159-15168, Oct. 2020.
0027-8424
10.1073/pnas.1920136117
1091-6490
Author
Van den Broeck, Frederik
Savill, Nicholas J.
Imamura, Hideo
Sanders, Mandy
Maes, Ilse
Cooper, Sinclair
Mateus, David
Jara, Marlene
Adaul, Vanessa
Arevalo, Jorge
Llanos-Cuentas, Alejandro
Garcia, Lineth
Cupolillo, Elisa
Miles, MIchael
Berriman, Matthew
Schnaufer, Achim
Cottori, James A.
Dujardin, Jean-Claude
Abstract
The tropical Andes are an important natural laboratory to understand
speciation in many taxa. Here we examined the evolutionary
history of parasites of the Leishmania braziliensis species
complex based on whole-genome sequencing of 67 isolates from
47 localities in Peru. We first show the origin of Andean Leishmania
as a clade of near-clonal lineages that diverged from
admixed Amazonian ancestors, accompanied by a significant reduction
in genome diversity and large structural variations implicated
in host–parasite interactions. Within the Andean species,
patterns of population structure were strongly associated with
biogeographical origin. Molecular clock and ecological niche modeling
suggested that the history of diversification of the Andean
lineages is limited to the Late Pleistocene and intimately associated
with habitat contractions driven by climate change. These
results suggest that changes in forestation over the past
150,000 y have influenced speciation and diversity of these Neotropical
parasites. Second, genome-scale analyses provided evidence
of meiotic-like recombination between Andean and
Amazonian Leishmania species, resulting in full-genome hybrids.
The mitochondrial genome of these hybrids consisted of homogeneous
uniparental maxicircles, but minicircles originated from both
parental species. We further show that mitochondrial minicircles—
but not maxicircles—show a similar evolutionary pattern to the
nuclear genome, suggesting that compatibility between nuclearencoded
mitochondrial genes and minicircle-encoded guide RNA
genes is essential to maintain efficient respiration. By comparing
full nuclear and mitochondrial genome ancestries, our data expand
our appreciation on the genetic consequences of diversification
and hybridization in parasitic protozoa.